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RIVER HEALTH ASSESSMENT FRAMEWORK,
INCLUDING MONITORING, ASSESSMENT AND
APPLICATIONS
Prepared by the International WaterCentre
Australia-China Environment Development Partnership
River Health and Environmental Flow in China
Project Code: P0018
April 2010
i
Document History and Status
Version Date Issued Prepared by Reviewed by
A1 20/Jan/2010 Chris Gippel Robert Speed, Stuart Bunn, Eva Abal, Nick
Bond, Fiona Chandler
B 16/Feb/2010 Chris Gippel Robert Speed, Stuart Bunn, Eva Abal, Nick
Bond, Fiona Chandler, Brad Pusey, Angela
Arthington, Tom Vanderbyl, Stuart Bunn
C 23/Feb/2010 Chris Gippel
Final 21/Apr/2010 Chris Gippel and Robert Speed Steering Committee
Distribution
Version Date Issued Method Issued to
A 20/Jan/2010 Email .pdf and .docx Robert Speed, Nick Bond
B 16/Feb/2010 Email .pdf and .docx Robert Speed
C 23/Feb/2010 Email .pdf and .docx Robert Speed
Final 21/Apr/2010 Email docx Chris Gippel
Document Management
Printed Not printed
Last saved 21-April-2010
File name River Health Framework_Final
Authors Chris Gippel and Robert Speed
Organisation International Water Centre Pty Ltd
Document name River Health Assessment Framework…
Document version Final
Suggested citation:
Gippel, C.J. and Speed, R. 2010. River health assessment framework: including monitoring,
assessment and applications. ACEDP Australia-China Environment Development Partnership,
River Health and Environmental Flow in China. International WaterCentre, Brisbane, April.
For further information on any of the information contained within this document contact:
International Water Centre Pty Ltd
PO Box 10907, Adelaide St
Brisbane, Qld, 4000
Tel: +61 7 31237766
Email: info@watercentre.org
www.watercentre.org
This publication may be of assistance to you, but the International Water Centre and its employees and
contractors do not guarantee that the publication is without flaw of any kind, or is wholly appropriate for
your particular purposes and therefore disclaims all liability for any error, loss or other consequence
which may arise from you relying on information in this publication.
ii
About this document
This document is one of a series three framework papers prepared to support work on the River Health
and Environmental Flow in China Project (‘the Project’). The three framework papers are:
River Health Assessment Framework, Including Monitoring, Assessment and Applications;
Environmental Flow Assessment Framework and Methods, Including Environmental Asset Identification and Water Re-allocation; and
A Holistic, Asset-based Framework for Evaluating River Health, Environmental Flows and Water Re-Allocation
The project objectives are to document and trial, in China, international approaches to river health and
environmental flows assessment. The trial involved three pilot river basins – the Yellow, Pearl and Liao
River Basins, with a sub-catchment selected from each. Further details on the pilot projects can be
found in the River Health and Environmental Flow in China Inception Report, 16 December 2010.
These three papers were prepared as a starting point for the pilot work. The methodologies and
framework outlined in these papers was refined during the course of the project, based on the results
of the pilot studies, as well as further research and discussion.
iii
Contents ABOUT THIS DOCUMENT ............................................................................................................... II
ABSTRACT (IN ENGLISH) ..................................................................................................VI
RECOMMENDATIONS.................................................................................................................... X
Objectives ............................................................................................................................. x
Benchmark for expressing relative river condition .............................................................. x
What and how to measure ................................................................................................. xi
Assessment and reporting................................................................................................... xi
Application ......................................................................................................................... xii
Ecological assets ................................................................................................................ xii
Stakeholder engagement. .................................................................................................. xii
Capacity building requirements ......................................................................................... xii
Framework ......................................................................................................................... xii
RECOMMENDATIONS (IN CHINESE) 建议 .......................................................................XIV
目标 .................................................................................................................................. xiv
表达相关河流状况的基准点 ........................................................................................... xiv
什么以及如何测量............................................................................................................ xv
评定 ................................................................................................................................... xv
应用 ................................................................................................................................... xv
生态资产 ........................................................................................................................... xv
框架 ................................................................................................................................... xv
INTRODUCTION ............................................................................................................... 1
RIVER HEALTH MONITORING ............................................................................................ 2
CONCEPT OF RIVER HEALTH AND RIVER CONDITION ........................................................................... 2
OBJECTIVES OF RIVER HEALTH MONITORING .................................................................................... 3
Types of monitoring ............................................................................................................ 3
Objectives of monitoring ..................................................................................................... 5
Recommendations: objectives ............................................................................................ 7
EXPRESSING RIVER CONDITION RELATIVE TO A REFERENCE OR BENCHMARK ........................................... 7
Reference condition ............................................................................................................ 7
Benchmark corresponding to a previous sampling round .................................................. 8
Benchmark corresponding to established standards or criteria ......................................... 8
Benchmark corresponding to standards for designated use ............................................ 10
Benchmark corresponding to management target .......................................................... 11
Recommendations: benchmark for expressing relative river condition ............................ 11
DECIDING WHAT AND HOW TO MEASURE ...................................................................................... 12
Components ...................................................................................................................... 12
Variables, data, metrics, indicators and indexes .............................................................. 14
Selecting variables that relate to manageable aspects of rivers ...................................... 17
iv
Monitoring environmental flows ...................................................................................... 17
Recommendations: what and how to measure ................................................................ 20
RIVER HEALTH ASSESSMENT AND REPORTING ................................................................ 20
OBTAINING CONTEXTUAL OR EXPLANATORY INFORMATION TO HELP INTERPRET RIVER CONDITION DATA .. 20
REPORTING AND COMMUNICATION ............................................................................................. 20
RECOMMENDATIONS: ASSESSMENT AND REPORTING ...................................................................... 21
RIVER HEALTH APPLICATION .......................................................................................... 21
RECOMMENDATION: APPLICATION .............................................................................................. 24
ECOLOGICAL ASSETS AND RIVER HEALTH MONITORING .................................................. 24
DEFINITION OF ECOLOGICAL ASSETS ............................................................................................. 24
RELEVANCE OF ECOLOGICAL ASSETS TO RIVER HEALTH MONITORING .................................................. 26
RECOMMENDATIONS: ECOLOGICAL ASSETS.................................................................................... 26
STAKEHOLDER ENGAGEMENT ........................................................................................ 26
ROLE OF STAKEHOLDER ENGAGEMENT .......................................................................................... 26
ELEMENTS OF STAKEHOLDER ENGAGEMENT ................................................................................... 27
RECOMMENDATIONS................................................................................................................. 27
CAPACITY REQUIRED FOR IMPLEMENTATION ................................................................. 27
RECOMMENDATIONS................................................................................................................. 27
RIVER HEALTH MONITORING IN AUSTRALIA ................................................................... 28
NATIONAL FRAMEWORK FOR THE ASSESSMENT OF RIVER AND WETLAND HEALTH (FARWH) ............... 28
ASPECTS OF METHODS USED BY JURISDICTIONS IN AUSTRALIA .......................................................... 28
Benthic macroinvertebrates .............................................................................................. 28
Fish assemblages .............................................................................................................. 29
Ecosystem processes ......................................................................................................... 29
Riverine vegetation ........................................................................................................... 29
Hydrology .......................................................................................................................... 30
Physical form ..................................................................................................................... 30
Water quality .................................................................................................................... 30
Driver indicators including catchment disturbance .......................................................... 31
The Filters approach .......................................................................................................... 31
Monitoring environmental flows ...................................................................................... 32
Products of river health monitoring .................................................................................. 32
COMPARISON OF THREE AUSTRALIAN PROGRAMS ......................................................... 32
SOUTH-EAST QUEENSLAND ECOSYSTEM HEALTH MONITORING PROGRAM (SEQ EHMP) .................... 32
VICTORIAN INDEX OF STREAM CONDITION (ISC) ............................................................................ 35
MURRAY-DARLING BASIN SUSTAINABLE RIVERS AUDIT (SRA) ......................................................... 39
v
COMPARISON........................................................................................................................... 42
Aims .................................................................................................................................. 42
Indicators .......................................................................................................................... 42
Sampling ........................................................................................................................... 43
Reporting frequency .......................................................................................................... 44
Common factors ................................................................................................................ 44
LESSONS FOR CHINA .................................................................................................................. 45
RIVER HEALTH MONITORING IN P. R. OF CHINA .............................................................. 45
STATE OF ENVIRONMENT REPORTING ........................................................................................... 45
LIAO RIVER .............................................................................................................................. 46
YELLOW RIVER ......................................................................................................................... 46
PEARL RIVER ............................................................................................................................ 47
MAIN ISSUES TO BE CONSIDERED IN DESIGN OF A RIVER HEALTH MONITORING PROGRAM
...................................................................................................................................... 47
RIVER HEALTH MONITORING FRAMEWORK .................................................................... 47
RECOMMENDATION: FRAMEWORK .............................................................................................. 47
REFERENCES .................................................................................................................. 48
vi
Abstract (in English)
Currently in China, the environmental condition of rivers is measured, and river management objectives
are set, primarily on the basis of routine water quality monitoring. Chinese agencies and technical
institutions recognise the need for a more rigorous approach which covers a comprehensive range of
indicators that reflect all aspects of the ecological health of rivers, including environmental water
requirements. This technical paper provides the foundation for the river health component of the
development of a holistic, asset-based framework for evaluating river health, environmental flows and
water re-allocation. The framework takes a comprehensive approach, and can be applied to any river
and any river health issue. The framework addresses hydrology, water quality, aquatic life, physical form
and habitat, and the streamside (riparian vegetation) zone.
For the purpose of this report, river health monitoring activities fall into four main types:
Routine monitoring
Monitoring the effectiveness of a management action
Compliance checking
Special investigations
Routine monitoring is concerned with a comprehensive program of regular and consistent observations
over a wide area. Monitoring the effectiveness of a management action is concerned with determining
whether or not a particular action intended to improve river condition achieves this aim. The basis of this
type of monitoring is hypothesis testing, and the selection of response variables and the appropriate
spatial and temporal scales at which to monitor will be governed by the hypothesis being tested.
Compliance checking is concerned with determining whether an agreed action intended to improve river
condition is actually implemented. For the example of environmental flows, the effectiveness of this
management action would be judged by improvements in river condition that can be statistically
associated with that action (as measured by indicators, including biotic attributes), while compliance
could be determined by analysis of hydrology. In the case of environmental flows monitoring, these two
types of monitoring would be required.
Special investigations cover the situations of environmental impact of a proposed development,
emergency monitoring of a pollution event, and scientific studies required to fill information gaps,
explore the links between cause and effect, test theory and develop predictive models.
In China there is a recognised need for a systematic, national approach to river health monitoring. The
approach would:
underpin the routine monitoring of river condition,
evaluate the impact of management actions, and
assist identification of priority rivers and river reaches for management attention
In practice, the objectives of river health monitoring in China are likely to vary from place to place, and
often a program will have multiple objectives. Most of the work to date appears to have focused on
highlighting known water quality issues. Improvement of water quality has been a major management
objective, and it is likely that efforts to remove industrial outfalls, and increase the urban sewage
treatment rate will result in dramatic improvements in water quality. At some point another degraded
aspect of the river environment will become limiting for the biota (e.g. hydrology, riparian vegetation, or
physical habitat). Without a comprehensive river health monitoring program in place that includes
bioassessment and measurement of driver and stressor variables, a failure of water quality
improvements to significantly increase the level of river health could go unrecognised, and there would
be a lack of information to guide the next phase of river rehabilitation.
vii
River health assessment focuses on the effects of human activity on the biological state of a river, with a
view to identifying the main degrading activities so they can be ameliorated. The logical reference point
then is the biological status in the absence of human disturbance, which explains why most river health
assessments are based on the concept of comparing current condition to natural conditions (structure,
composition, function, diversity) in the absence of human disturbance or alteration.
Most rivers in China, except some headwater reaches in mountainous regions, are disturbed in some
way. Many of the alterations have been in place for centuries or even thousands of years, particularly in
the lowland areas. Given the lack of reference sites in China, it may be preferable to set as the
benchmark the best attainable condition. Best attainable condition is equivalent to the expected
ecological condition of least-disturbed sites if the best possible management practices were in use for
some period of time. Sites in BAC would be places where the impact on biota of inevitable land use is
minimized.
The hierarchy of measurement in a river health monitoring program begins at the scale of the simplified
ecosystem components and the drivers of ecosystem processes. These components could also be
referred to as themes, or elements of the program. The main components are:
Catchment processes
Instream physical processes (hydrology and geomorphology), which also give rise to hydraulic
conditions
Water quality and sediment chemistry, which also includes contaminant loads
Aquatic and riparian life, which include flora, fauna and ecosystem processes
The components can be arranged in a rough hierarchy of drivers to responses, but some responses are
also drivers of other processes - the components are linked through physical, chemical and ecological
processes. A program can concentrate on one component, combine a number of components or, for
particular reaches, river basins, or regions, select from a group of program-approved components to suit
local ecosystem conditions, management issues, and available resources. Clearly, the more
comprehensive is the program the more information it generates about the status of river health, the
cause of identified river health problems and how to best manage the river to improve river health.
However, apart from the issue of cost, it may be that some components are not worth including because
they lack sensitivity to likely variability in river health over space and time. When considering what
components to include in a river health monitoring program there are three choices:
1. At the outset, design the program as a comprehensive one that includes driver/stressor and
response components, test the utility of a large number of variables in pilot studies, and then
trim the list to the most effective variables.
2. Begin with a bioassessment program that is limited to the most promising response variables
(selected on the basis of what is known of the rivers proposed for monitoring, and those proven
in the literature), then periodically review the program and add driver/stressor components as
necessary, or
3. Commit to a bioassessment-only program, and gather information on the drivers/stressors of
river health under a separate program.
Choosing a suite of variables to measure is a challenging aspect of river health monitoring program
design. The main characteristics of effective river health indicators are:
1. quantify and simplify complex ecological phenomena;
2. provide easily interpretable outputs
3. respond predictably to damage caused by humans while being insensitive to natural spatial or
temporal variation;
4. relate to an appropriate scale;
viii
5. relate to management goals; and
6. be scientifically defensible
There are many different standard ways to measure the selected ecosystem components. The most
expedient approach would be to adopt protocols that have proven successful elsewhere, but it is likely
that adaptation will be required to suit local conditions.
Two types of monitoring are appropriate for environmental flows:
Compliance monitoring to determine if the environmental flow provisions were followed (i.e.
were the environmental flows delivered to the river as specified)
Routine monitoring to test the hypothesis that environmental flows will lead to improved river
health (i.e. did river health improve as expected in response to the implementation of
environmental flows?)
In monitoring environmental flows, hypothesis testing refers to a number of ‘predictions’ or ‘questions’
that are to be tested. For any particular river, the foundations of the hypotheses to be tested can be
found in the environmental flow assessment documentation. Of course, this assumes that the
environmental flows method being used is one based on a conceptual understanding of the flow-
ecosystem relationships, as opposed to one based on simple hydrological rules of thumb.
While river health monitoring is concerned with data generation, river health assessment is concerned
with analysis and interpretation of those data. The assessment provides information that aids
management decisions. The products of the assessment are reports that interpret the results of
monitoring in the context of the objectives of the program, show spatial distributions, analyse for trends
in the data, and attempt to explain the results in terms of the causative factors. It is likely that the
assessment process will draw on data and information from sources external to the river health
monitoring program.
It may be appropriate for report cards to report on river condition based on a number of different
benchmarks. Report cards will need to be designed in a way that ensures they provide an accurate
picture of river health, recognize differences in river health across a wide-range of basins where overall
river health is likely to be poor, and provide appropriate incentives for management action. Targets
should not be set either too high (where they cannot realistically be achieved) or too low, where they
may be too easily met.
Application of the results of river health monitoring occurs when actions are taken in response to the
assessment. This will only occur if an appropriate policy mechanism is established.
River health monitoring is not value-free. Subjective decisions have to be made with respect to what
variables will be measured, where they will be measured, and how the data will be reported. The
ecological asset-based approach to management focuses on protecting key assets, usually particular
independently defined sites of high conservation value. A process-based approach to management
focuses on maintaining or restoring the physical, chemical and biological processes that sustain
ecological assets.
The concept of ecological assets and key ecological assets are most relevant at the stages of river
health program design, and utilization of program results to river management. If the main objective of a
river health monitoring program is to inform management of independently defined ecological assets
(sites or processes), then the monitoring only needs to be undertaken at the relevant sites or where the
processes of interest occur. Alternatively, the monitoring might be used to help identify the ecological
assets, the risks to those assets, and thus where investment in resource management would be most
effectively directed.
There is a range of stakeholders that may be able to contribute to the development and implementation
of a river health monitoring program. Consideration should be given to:
Which stakeholders should be engaged in the process
ix
The objectives of any stakeholder engagement
The stages during development and implementation of a program when different stakeholders
should be engaged
The best mechanism(s) for engaging stakeholders
A comparison of 3 major Australian river health monitoring programs (the South East Queensland
Ecosystem Health Monitoring Program, the Victorian Index of Stream Condition and the Murray-Darling
Basin Sustainable Rivers Audit) found that the programs differed significantly in a number of respects.
However, all three are widely regarded as having successfully met their objectives. The factors that they
do have in common, and which may be the main determinants of success, are:
Embedded within, and considered a critical component of, a wider river health strategy,
Well formulated and clearly articulated objectives,
A well funded phase of scientific program development and pilot testing in order to establish
indicators and protocols that would meet the agreed program objectives,
Technical manuals, operator training, and attention to quality control and assurance,
River condition reported relative to an established reference condition (although this can be
defined in different ways),
Strong levels of commitment by government and community,
Established formal links to river management,
Including indicators that directly measure the drivers and stressors of river health, or having
that informational available to the program to assist in explanation of water quality and
biological data,
Transparent, effective, and publicly accessible reporting, and
Ongoing critical review of the programs methods, and refinement and development as
necessary.
The implications of the comparison of 3 Australian programs for development of river health monitoring
programs in China are that:
Close attention needs to be paid to the factors that the Australian programs had in common,
and which may be key determinants of success,
The set of indicators should be chosen to suit the local conditions and the local objectives
rather than simply being copied from another program from another part of the world,
The program can focus on water quality and bioassessment, provided contextual information
on drivers and stressors is available, and provided the chosen indicators are diagnostic of
management issues – alternatively, the monitoring program can include driver/stressor
indicators that relate directly to intended management actions,
Full characterisation of spatial pattern and reliable trend detection in physico-chemical water
quality parameters requires an extensive network of frequently monitored sites, operational for
a long period of time, so the existing network in China should be utilised,
For field measured variables, careful attention should be paid to design of the sampling
strategy (sampling site location, number of sites, sampling frequency, and timing of sampling),
especially if one of the objectives is change detection, and
The reporting frequency needs to be appropriate to the expected rates of change in the chosen
indicators, and the benefits of frequent reporting need to be balanced against the cost of doing
so.
x
The main issues to be considered in design of a river health monitoring program for China are:
1. Objectives of the program (to be established by responsible agencies)
2. Sampling strategy (site location, number of sites, site selection strategy, frequency of sampling,
with an emphasis on scientifically sound methods)
3. Indicators selected for monitoring (relate to issues, assets, program objectives and likely
management activities, plus consider US EPA EMAP criteria). Either test a large number of
possible indicators in pilot studies, or chose a small number of indicators that are proven in the
literature.
4. Selection of suitable benchmark – must be consistent nationally
5. Quality Control/Quality Assurance methods
6. Production of manuals
7. Data management
8. Analytical methods (statistics, and development of composite index)
9. Sourcing contextual information to explain river health observations.
10. Reporting and communication methods (a policy is required for data and report access)
11. Timing and mechanism for engaging stakeholders in the program
Recommendations
Objectives
1. A program of river health monitoring in China should sit within a wider river health strategy that
explicitly links the results of monitoring to management responses.
2. A wide-scale program is required for routine monitoring, while testing the effectiveness of
environmental flows will require special hypothesis-based monitoring programs.
3. As the objectives of monitoring programs are likely to vary from place to place, it will be
necessary to allow flexibility in the selection of sampling strategies and the selection of
indicators to monitor.
Benchmark for expressing relative river condition
4. Most rivers in China, except some headwater reaches in mountainous regions, are disturbed in
some way. Many of the alterations have been in place for centuries or even thousands of
years, particularly in the lowland areas. It will not be possible to define MDC (minimally
disturbed condition) or HC (historical condition) for most regions. LDC (least disturbed
condition) would likely represent a relatively disturbed condition in most places. It is likely that
an alternative to the traditional concept of reference will be required for China.
5. Given the lack of reference sites in China, it may be preferable to set as the benchmark the
best attainable condition (BAC) for the designated river use within existing functional zones. In
the vast majority of cases this will leave room for improvement over current condition. It is
envisaged that the BAC would be independently defined through a scientific process. It would
be a matrix that covered particular river attributes, for any given class of use, scale of river,
geomorphological setting, and eco-hydrological river class.
6. The BAC would not necessarily correspond with the working management targets set to
achieve short-term goals at any particular time, but it would represent an ideal long-term target,
and a consistent set of benchmarks from which to compare like rivers at the national level.
Once a river prioritised for management action achieved the target level of river health, the aim
xi
of management would be to maintain BAC in that river, with rehabilitation resources then
directed to improving the condition of another high priority river. Of course, management
authorities would also have the prerogative of changing river use class, in order to pursue
achievement of even higher levels of stream health.
7. Sites for characterising BAC are unlikely to be available in China. In this case, established
standards or criteria determined using any practical method, with expert opinion likely to be
required, at least in the initial establishment of the matrix.
8. One potential problem with using management targets as the benchmark for river health arises
when the targets are intentionally unambitious in order to give the impression of a high level of
achievement of expected river health. This result may create a superficial and temporary sense
of achievement, but it would provide little motivation to further improve stream condition. It is
important then to adhere to the principle that long-term management targets correspond to a
genuine BAC.
9. Another potential issue with BAC is that continued development of water resources could lead
to an unremarked decline in absolute levels of river health – unremarked because when an
undeveloped river with close to natural stream health targets is developed, its use is simply re-
designated to a lesser class, with less stringent health targets. Thus, prior to, and after, the
development, the river may have met the appropriate health target, but absolute health would
likely have declined. Of course, such declines would to some extent be offset by improvements
to stream health achieved in other previously poorly managed rivers. This issue is not so much
to do with the choice of river condition benchmark, but more to do with development and
implementation of appropriate policies concerning water resources development.
What and how to measure
10. This report does not recommend a suite of indicators that should be included in a river health
monitoring program for China. It may be necessary to evaluate a broad range of indicators
(selected after first assessing them against US EMAP criteria) in pilot studies, and then select
those that best respond to known disturbance gradients. If expediency is required, then
bioassessment using a small number of indicators known from the literature to be sensitive to
the form of water quality impairment typical of China’s rivers would be the best starting point.
11. Assessment of environmental flows involves two components: hydrological compliance
monitoring, and hypothesis-based ecological/geomorphological response monitoring.
Practicalities will often mean that a BACI (Before After Control Impact) program design is not
possible, but other designs can also be effective. It will be necessary to judiciously select
variables and sites, with a focus on monitoring those variables or sites where the expected
response magnitude is large.
12. Whatever indicators are chosen, it is critical that the river health monitoring program follow
rigorous scientific protocols in selecting sites, determining sampling frequency, field sampling
and measurement, laboratory measurement, and statistical analysis. The expedient approach
is to adopt proven standard methods.
Assessment and reporting
13. It is important to interpret the results of the monitoring to match the objectives of the program.
The findings should be reported using a range of formats, to a range of audiences.
14. One of the key products should be report cards, ideally produced annually.
15. The basic reporting unit should correspond with the established water function zones. These
are currently used for water quality reporting. Depending on the distribution of these zones, it
may be necessary to aggregate zones to cover larger areas.
xii
16. It may be appropriate for report cards to include information related to status against a number
of benchmarks. These may include BAC, shorter-term management targets such as the
achievement of water function zone requirements, and condition relative to previous years.
Application
17. Application involves linking the monitoring program to policy. A mechanism needs to be in
place for transferring the results of monitoring to the agencies responsible for management
actions.
Ecological assets
18. A liberal definition of ecological asset is appropriate, including biodiversity, threatened species,
native species, species of high conservation value, certain habitats, certain ecological
processes, ecosystem services and certain places.
19. River health monitoring can be used to help identify ecological assets, the risks to those
assets, and thus where investment in resource management would be most effectively directed
Stakeholder engagement.
20. Development and implementation of a river health monitoring program should be supported by
a framework for engaging stakeholders at appropriate stages during the process.
Capacity building requirements
21. The skills required to implement any monitoring program, and the feasibility, time and cost
involved in training relevant staff in those skills, should be a consideration in designing an
appropriate program.
Framework
22. A generic high-level river health monitoring framework for China is presented below. This
framework is intended to guide the establishment of a structured river health monitoring
program within a river health strategy. Details of indicators, protocols and communication tools
will likely vary from area to area, depending on local conditions and priorities.
xiii
Stream health application
Set targets, priorities, methods, allocations; implement activities
Stream health assessment
Stream health monitoring
Data on drivers and stressors
Formal links:science-community-
management
High level management principles• Protect and improve river health• Optimise for social and economic benefit
Appropriate indicators and
protocols
RespondCommunicate
ExplainFundamental
research
Integrated River Basin Management (IRBM) activities, Environmental flows, Water Resource Allocation
Plans (WRAP), Environmental Impact Assessment (EIA)
Observe trend and pattern at
basin-scale
Test response to specific
action
Report nationally
Gather dataObjective
Generic framework for river health monitoring in China
xiv
Recommendations (in Chinese) 建议
目前在中国,河流的环境条件是测量的,河流的管理目标是确定的,基本是根据对日常水质量的检测。
中国的专业机构和技术部门已经意识到,需要严格的手段来确保所有的措施能够涵盖整个河流环境流监控
的各项指标。这其中包括环境流的必要量。这一份技术材料提供了一个河流健康的基础,全盘开发的重要
组成部分。资产基础的河流健康评估的框架,环境流和水的重新分配。这个框架基于一个综合的角度,因
此能够适用于任何河流或者任何河流健康问题。此框架表述了水文学,水质量,水生生物,物理构成以及
栖息地和河边地带区域(河边植被)
目标
1, 在中国,
一项河流健康监测系统的建立,应当建立在广泛的河流健康战略中,以使其明确地联接到监测管
理的结果。
2, 一个大范围系统要求日常的检测,同时在测试环境流的有效性时,要求特殊的虚拟检测系统
3, 由于检测系统的目标根据地点的不同都有变化,将有必要允许一定的灵活的措施和检测地点的选
择。
表达相关河流状况的基准点
4, 中国的大部分的河流,除了一些在源头的水流向山区,大部分都分成若干干流。有许多历经世纪
或者千年的变化,特别是在下流流域。这在很多地区就不完全能够定义MDC(最低限度地分流
条件)或者HC (历史条件)。LDC
(最少分流条件)可能会代表大部分地区的相对的分流条件。很有可能需要有一个适合中国河流
自身传统概念的选择办法。
5, 鉴于在中国少有参考点,或许更适宜于使用基准点的办法,在现存的功能区域指定的河流作为(
BAC)最可达到的方式。在目前条件,相当大的情况下,这个方法将留有很大的待改进的空间。
这个设想,BAC能够通过科学的独立确定。这同时将是一个矩阵的方式,涵盖了独特的河流分流
。对于任何一个级别的拥护,河流刻度,地貌区定以及环境水文河流的级别。
6, BAC并不一定会对短期目标所确立的管理目标有必要的回应,但是一定会对其长期目标以及从对
相像河流的国家级别的一致性的基准点有所回应。一旦确立河流管理的优先程序,达到预期的河
流健康的各级标准,管理目的就在于如何维护在此河流中的BAC,
通过修复资源,然后引导到如何改进另一个高优先程序的河流的条件。当然,
管理当局应当同样有更改河流用户级别的特权, 以便进行更高一个级别的溪流健康。
7, BAC中所表述的站点在中国似乎不太好提供。
鉴于这样的原因,建立的标准或条件决定了使用任何实用的方法,当然专家的意见也一定是需要
借鉴的。至少在矩阵最初建立的时候。
8, 一个潜在的问题会出现,在使用管理目标作为基准点时,各项目标有意识地表现为并不十分明显
,为的是给出一个印象比较高的河流健康的管理成果。
这个结果可能造成一个较肤浅和短暂的成果显示,但是有可能给与比较微弱的动力以便日后的进
一步改善溪流的条件。这就意味相当重要的是坚持一个长期的管理目标以针对真实的BAC结果。
9, 另一个潜在的因素是,持续的开发水资源,可能导致一个无法重新记录的绝对水平持续降低的河
流健康信息。无法重新记录是因为当一个并没有开发的河流但是离自然溪流健康目标的开发很紧
xv
的河流。
它的方法就是简单地从新设计一个更低等级的设计,包括低迫切度的健康目标,但是绝对的健康
就将递减。当然,这种递减在某种程度上由于对原来较弱的河流健康管理的改进而抵消。
这种情形并不与选择河流基准点有太大的关联,只是更多的影响水资源开发的有效管理和正确举
措。
什么以及如何测量
10, 在中国,这份报告并不建议使用一系列的指示器运用到河流健康监测系统。当然也需必要在初步
研究的时候使用范围较广的指示器的评估,然后选择那些回应渐变干扰最佳的指示器。如果权宜
之计需要,生物评估,就是使用一个小数字的指示器,从文献中知道,这样对中国的典型河流水
质量损坏的敏感度测试时一个最好的开端。
11, 评价环境流包括两个部分:适应水文的监测,
以及虚拟基础的生态/地貌回应的监测。实用性方面,将经常意味着BACI(之前之后控制冲突)
系统的设计 是不可能的,
但是其他的设计也有可能很有效。这就是说有必要明智地选择变量和站点,主要集中于监测那些
回应比较强烈的变量和站点
12, 无论选择什么样的监测器,
关键在于河流监控系统严格地按照科学的方式选择站点,决定采样频率,野外抽样和测量,
实验室测量,以及统计分析。权宜之计是采用已经证明适用的标准方法。
评定
13, 重要的是阐述监测的结果与目标系统的吻合。检查结果要用一系列的格式,针对一系列的用户。
14, 其中的一个关键产品是报告卡,最理想的是年报。
15, 基本的报告单元应当与水作用区域的建立相结合。或许有必要集中区域以包括更大的面积。
应用
16, 应用包括了连接监测程序和政策。一个机械设备应当放置在一个能够转移监测结果以适应管理的
需要。
生态资产
17, 一个宽泛的生产资产的定义是适当的。包括生物多样化,濒危物种,
原生物,高保存价值的物种,一定的栖息地,一定的生态过程以及一定的地点。
18, 河流健康监测器可以用于鉴别生态资产,对这些资产的危险性,从而如何指导对资源管理的最有
效的投资。
框架
19, 一个针对中国普遍性的高一层河流健康监测框架如下所示:此框架目的在于指导建立在一个河流
健康策略下的河流健康监测程序的结构。具体的监测器,协议以及沟通工具将因地区和地区的不
同而有所变化,完全取决于当地的条件和优先程序。
xvi
溪流健康应用
设定目标, 优化组合, 方法, 分配; 实施行动
溪流健康评估
溪流健康监测
驱动器和压力数据
正式的链接:科学-社区-管理
高层管理原则•保护和改善河流健康•优化对社会和经济的利益
恰当的指示器和协议
反应沟通
解释基础研究
整合河流管理 (IRBM) 活动, 环境流, 水资源分配计划
(WRAP), 环境影响评估 (EIA)
以盆地刻度来观察趋势和模式
针对特别活动的测试
国家级的报告
收集数据目标
中国河流健康监测的通用框架
1
Introduction
Currently in China, the environmental condition of rivers is measured, and river management objectives
are set, primarily on the basis of routine water quality monitoring. Chinese agencies and technical
institutions recognise the need for a more rigorous approach which covers a comprehensive range of
indicators that reflect all aspects of the ecological health of rivers, including environmental water
requirements. What is required is a systematic, nationally consistent approach that would underpin the
monitoring of river condition, evaluate the impact of management actions and, assist in the prioritisation
of rivers and river reaches for particular management attention.
The new River Basin Masterplans for the 7 major river basins in China will make provision for
environmental flows, which recognise and balance environmental needs with other demands on the
water resource. Once agreed, an environmental flow provisions will be included in the water allocation
arrangements and annual water allocation plans for the river basins.
This technical paper provides the foundation for the river health component of the development of a
holistic, asset-based framework for evaluating river health, environmental flows and water re-
allocation (Gippel and Speed, 2010a). The framework takes a comprehensive approach, and can be
applied to any river and any river health issue. The framework addresses hydrology, water quality,
aquatic life, physical form and habitat, and the streamside (riparian vegetation) zone. A second technical
report (Gippel and Speed, 2010b) provides the foundation for the environmental flow and water re-
allocation components of the framework.
There is a great range of river health monitoring programs in place around the world; this report does
not attempt to review them all. The review is based largely on existing Australian practice, with an
emphasis on broad approaches and important generic principles. Other methodological aspects of the
project, such as detailed protocols for field measurement, quality control and quality assurance, data
management, statistical methods, and report presentation formats, will be developed throughout the
course of the project to specifically suit the adopted methodology.
In this report, river health monitoring, which is primarily concerned collection and reporting of data, is
distinguished from river health assessment, which involves the analysis and reporting of the
implications of those data for resource management (following EMT, 1997, p. 17). Application of river
health data and assessment refers to utilisation of the information to improve resource management.
These three elements are normally integrated within a wider river health strategy (Figure 1), which is the
planning framework that aims to balance environmental, economic, recreational and cultural needs to
achieve healthy rivers. Environmental flow assessment, environmental asset identification, river health
target setting, and water re-allocation are also important components of such a strategy (Figure 1).
River health monitoring can be undertaken independently of a wider river health strategy, but the value
of such an exercise is weakened by the absence of a formal link to management action. The framework
for evaluating river health, environmental flows and water re-allocation, which this technical paper
complements, is not a fully specified river health strategy for China, but it does address some core
elements of such a strategy.
2
Figure 1. Connections between environmental asset identification, setting river health targets, environmental flow assessment, flow re-allocation, and river health monitoring, assessment and application within a river health strategy. Fundamental scientific research may be conducted outside the river health policy realm (i.e. independently funded) but interactions occur through utilization of data generated by the river health program or by informing river health monitoring, assessment and application through research results. The management process model is from Rogers and Biggs (1999). The river health responses and questions indicated are examples only – in practice there are many more.
River Health Monitoring
Concept of river health and river condition The term ‘river health’ is often equated with ‘biological integrity’ (Boulton, 1999), defined by Frey
(1977) as:
“the capability of supporting and maintaining a balanced, integrated, adaptive community of
organisms having a composition and diversity comparable to that of the natural habitats of the
region”
This definition [also rephrased as ecosystem integrity by Karr and Dudley (1981), Schofield and Davies
(1996) and Davies et al. (2008)] implies that river health is an absolute concept that cannot have
degrees, i.e. biological or ecosystem integrity is intact, being comparable to an undisturbed stream
(stream is healthy) or it is not (stream is not healthy). In practice, river health is measured using indices
that are intentionally selected to vary along a gradient of environmental disturbance, so there is a scale
Realm of a River Health Strategy
Environmental flow
assessment
Components to be managed or regulated, such as: environmental flows, pest species, sewerage treatment, industrial effluent, revegetation, channel stability, sand and gravel extraction, hydropower, stock access, fisheries, fish passage, etc.
Recommend flow needs
Trade-off and re-allocate
flows
Needs of industrial,
agricultural, recreational and urban
users
Desired state –operationalisedhealth targets
River health assessment
Is the river healthy?
Diagnose cause
Measure and report data
Should e-flows be reviewed?
Prioritise riversPrioritise actions
River health application
Identify environmental
assets
Check compliance
River health monitoring
Policy mandate
Operational goals
Problem definition
Potential solutions
Evaluate and select
Implement
Management process model
Fundamental scientific investigation – tests of theory
3
of deviation from the healthy state. To avoid confusion, it may be preferable to use the term ‘river
condition’ when describing the degree of deviation from a healthy state, rather than using ‘condition’
and ‘health’ synonymously. For example, in the Sustainable Rivers Audit (SRA) of the Murray-Darling
Basin (http://www.mdba.gov.au/programs/sustainableriversaudit) (Davies et al., 2008), the capacity of
an ecosystem component to support key processes (e.g. carbon exchange, energy transfer, nutrient
cycling) is referred to as its ‘condition’, described by structural and functional measurements. A river
ecosystem is deemed ‘healthy’ when its essential character is maintained over time (Davies et al.,
2008).
River condition reflects the overall state or character of a river and can be described using various
indices that apply to certain attributes of rivers. River condition is measured relative to an arbitrary
benchmark or reference condition. The benchmark condition can be the pristine state [i.e. ecosystem
integrity intact, using the definition of Karr and Dudley (1981)] or an ecological state that represents a
known departure from this ideal.
Various authors, including Metcalfe-Smith (1996), Barbour et al. (1999) and ANZECC and ARMCANZ
(2000a; 2000b; 2000c), reviewed the traditional and more recently developed approaches to monitoring
river condition. Historically, environmental assessment of streams was based on physico-chemical
measures of water quality. Physico-chemical profiling may identify situations where biotic
communities are at risk, but provides no information on the actual damage, if any, to the biota. Even
where the tolerances of organisms to individual pollutant concentrations are known, this information may
have limited application to the common situation of streams being affected by multiple pollutants, as well
as habitat disturbance, and hydrological alteration.
Rather than measuring the physical and chemical factors that give rise to stream health,
bioassessment methods directly measure the condition of the aquatic biota. Compared with full
physico-chemical characterisation, targeted bioassessment requires less equipment and a large area
can be surveyed intensively in a short time. Bioassessment originally focused on benthic
macroinvertebrate assessment, but these approaches now also include periphyton, vegetation, fish and
other components of the aquatic system. The weakness of undertaking bioassessment alone is that it
provides only indirect information on the potential causes of any observed biological effects.
Holistic methods of measuring river health include a range of indicators. River condition can be
expressed as a string of sub-index values, or as a single integrated index, without concern for mixing
cause (abiotic drivers or pressures) and effect (biotic response) attributes. Common driver/pressure
variables include physical habitat availability, hydrology, riparian vegetation, physical form and process,
and water quality (e.g. Ladson et al., 1999; Parsons et al., 2002). Including driver/pressure variables
enhances the capacity to diagnose the cause of river health problems, and to identify the issues that
require management action.
Objectives of river health monitoring
Types of monitoring
In a report to the U.S. E.P.A., the Study Group on Environmental Monitoring (1977) described three
categories of environmental monitoring relevant to pollutants, with each designed to answer different
questions: source monitoring, which addresses the questions of what pollutants, where they come
from and in what amounts; ambient monitoring, which measures the concentrations of pollutants in the
physical and biological environment; and, effects monitoring, which measures the consequences of
the pollutants for living things. These categories are not readily transferable to holistic river health
monitoring.
Compliance monitoring is the routine collection of data to check that activities that potentially degrade
river health are operating within legally enforceable guidelines or criteria. Most often this concept applies
to monitoring of concentrations and loads of pollutants in effluents discharged to rivers, but it could
4
equally apply to monitoring discharge to determine whether environmental flow targets are being met by
the responsible river management authority.
The EU Water Framework Directive (Kallis and Butler, 2001) distinguishes between three types of
monitoring: surveillance monitoring provides a coherent and comprehensive overview of current
health status, and an assessment of long-term changes, at the scale of large river basin districts;
operational monitoring for those water bodies (down to 10 km²) that are identified to be at risk of
failing to meet environmental objectives, and for monitoring changes in the status after rehabilitation
measures, and; investigative monitoring for those water bodies that have failed, or are likely to fail, to
meet the environmental objectives for unknown reasons or to ascertain the magnitude and impacts of
accidental pollution. In other places, surveillance monitoring, as described above, is referred to as trend
monitoring or routine monitoring. Operational monitoring can also be referred to as restoration
assessment or campaign monitoring (MDBC, 2003), and investigative monitoring can be referred to
as impact assessment.
Snapshot assessment (e.g. Norris et al., 2001; National Water Commission 2007) is a once-off effort
designed to rapidly obtain a picture of the current state of river health over a given area. The emphasis
is on the spatial patterns in the data. If the snapshot involves field sampling, then the result is only
relevant to the prevailing hydrological and seasonal conditions. The snapshot could also be based on
existing data.
For the purpose of this report, river health monitoring activities fall into four main types:
Routine monitoring
Monitoring the effectiveness of a management action
Compliance checking
Special investigations
Routine monitoring is concerned with a comprehensive program of regular and consistent observations
over a wide area. Monitoring the effectiveness of a management action is concerned with determining
whether or not a particular action intended to improve river condition achieves this aim. The basis of this
type of monitoring is hypothesis testing, and the selection of response variables and the appropriate
spatial and temporal scales at which to monitor will be governed by the hypothesis being tested.
Compliance checking is concerned with determining whether an agreed action intended to improve river
condition is actually implemented.1 For the example of environmental flows, the effectiveness of this
management action would be judged by improvements in river condition that can be statistically
associated with that action (as measured by indicators, including biotic attributes), while compliance
could be determined by analysis of hydrology. In the case of environmental flows monitoring, these two
types of monitoring would be required.
Special investigations cover the situations of environmental impact of a proposed development,
emergency monitoring of a pollution event, and scientific studies required to fill information gaps,
explore the links between cause and effect, test theory and develop predictive models. For example,
special scientific investigations may be required in the case of the supposed causes of poor river health
being addressed through management, but this not being reflected in improvements in measures of
biological health. Essentially, such a study is a test of the theory that predicts river condition as a
function of management actions. The results would lead to improvements in either the way stream
condition is measured, or the way the issues are managed (or both). In developing a river health
program it will be necessary to undertake pilot studies that are rigorous scientific tests of proposed
methods. These fall into the class of special investigations. Special investigations would be
1 Compliance also includes routine checking of water quality (usually of effluents) against agreed standards – this is
not a topic of this report.
5
commissioned on a needs basis, so they are not included as a central component of a river health
monitoring program.
Objectives of monitoring
River health monitoring is undertaken as part of a strategy to protect and enhance the health of riverine
ecological assets (where impairment is caused by human actions) (Figure 1). The overarching objective
is to provide information on river ecosystem state and functioning that guides rational river management
actions and on-ground actions. The goal of management may be to achieve a target state of river
health, to maintain the current status, or to improve on the current status.
Individual river health monitoring programs can have one or more objectives, and these have
implications for the design of the program (Table 1). As well as site selection, and variable selection, the
program objectives will help to determine the required monitoring site density, and the frequency and
duration of observations. For example, the monitoring program for the Murray-Darling Basin Living
Murray initiative (http://www.mdba.gov.au/programs/tlm/programs_to_deliver/environmental_monitoring)
is limited spatially to six pre-defined icon sites (i.e. chosen for their high ecological, cultural, recreational,
heritage and economic value, not selected on the basis of monitoring data) to inform a program of
targeted environmental flows and a targeted program of stream works and measures. This contrasts
with the Sustainable Rivers Audit (SRA) routine monitoring program which aims to provide a consistent
and comprehensive picture of the health of the rivers throughout the entire Murray-Darling Basin, and to
monitor changes in health through time. Thus, the SRA adheres to strict protocols regarding random site
selection, site density to achieve a certain statistical power, and repeat surveys through time.
In China there is a recognised need for a systematic, national approach to river health monitoring. The
approach would:
underpin the routine monitoring of river condition,
evaluate the impact of management actions, and
assist identification of priority rivers and river reaches for management attention
In practice, the objectives of river health monitoring in China are likely to vary from place to place, and
often a program will have multiple objectives. Most of the work to date appears to have focused on
highlighting known water quality issues. Improvement of water quality has been a major management
objective, and it is likely that efforts to remove industrial outfalls, and increase the urban sewage
treatment rate will result in dramatic improvements in water quality. At some point another degraded
aspect of the river environment will become limiting for the biota (e.g. hydrology, riparian vegetation, or
physical habitat). Without a comprehensive river health monitoring program in place that includes
bioassessment and measurement of driver and stressor variables, a failure of water quality
improvements to significantly increase the level of river health could go unrecognised, and there would
be a lack of information to guide the next phase of river rehabilitation.
Hypothesis-based monitoring will likely be necessary for assessing the effectiveness of implementation
of environmental flows. The improvements in river health from environmental flows alone may be too
subtle to be detected by routine monitoring. In most cases, there is uncertainty about the outcome of
environmental flows (due to uncertainty in the theory and empirical data used to formulate the
recommended flows), so implementation should be accompanied with monitoring to aid adaptive
management. This monitoring will require careful planning to avoid confounding factors and to make
sure that hypotheses can be meaningfully tested.
6
Table 1. River health monitoring program objectives, and implications for site and variable selection, and monitoring frequency.
Program Objective Issues Responses Specific objective Site selection implications
Variable selection implications
Test and improve effectiveness of
management actions Known Implemented
Test effectiveness of, and adaptively manage, specific management actions
Stratified according to where actions are and are not applied
Response variables that relate to project objectives
Test effectiveness of, and adaptively manage, site specific application of management actions
According to location of actions
Response variables that relate to project objectives
Compliance checking against stated limits
Points of compliance Variables listed for compliance (usually water quality)
Collect data to inform policy development
Known Not formulated Observe spatial pattern and trend in variables related to specific issue of concern
Known sites where issue has been identified
Variables that relate to the issue (e.g. fish passage, bank erosion)
Unknown Not formulated
Provide data to develop policy priorities for specific types of actions
Random over extent of region where actions likely to be applied
A range of driver and response variables, plus monitor management actions
Provide data to develop policy priorities for actions at specific areas (e.g. icon sites, geomorphic zones within basins)
Random within the specific areas
A range of driver and response variables, plus monitor management actions
Communication
Awareness of general issues, but issues
secondary to health message
Awareness of general responses, but
responses secondary to health message
Raise public awareness of river health as an issue, to support policy implementation
Random over region of interest, or target rivers of main public interest
Simple set of response variables
Provide comparative data to motivate regional river managers and stakeholders to implement actions to improve river health
Random sites over region of interest, with coverage of most major streams
Simple set of response variables (to motivate, but need driver data to take action)
Inform the public of the state of river health as part of accountability obligations
Random over region of interest, or target rivers of main public interest
Simple set of response variables
7
Recommendations: objectives
1. A program of river health monitoring in China should sit within a wider river health strategy that
explicitly links the results of monitoring to management responses.
2. A wide-scale program is required for routine monitoring, while testing the effectiveness of
environmental flows will require special hypothesis-based monitoring programs.
3. As the objectives of monitoring programs are likely to vary from place to place, it will be
necessary to allow flexibility in the selection of sampling strategies and the selection of
indicators to monitor.
Expressing river condition relative to a reference or benchmark
Reference condition
River health assessment focuses on the effects of human activity on the biological state of a river, with a
view to identifying the main degrading activities so they can be ameliorated. The logical reference point
then is the biological status in the absence of human disturbance, which explains why most river health
assessments are based on the concept of comparing current condition to natural conditions (structure,
composition, function, diversity) in the absence of human disturbance or alteration (Stoddard et al.,
2006).
The reference condition of a river attribute is a distribution rather than a single value. The range of
values results from sampling error and natural variability, both in space and time. Once the distribution
is defined, parameters in the distribution (such as certain arbitrary percentile values) can be used as
benchmarks from which to judge the condition of test sites.
The term ‘reference condition’ has been used to refer to biological states different to undisturbed. To
avoid confusion and misunderstanding, Stoddard et al. (2006) defined five different versions of
reference condition, although they recommended that the term ‘reference condition’ be reserved for its
original conception.
Reference condition for biological integrity, RC(BI)
The condition at the present time in the absence of human disturbance (as adopted in principle for the
Clean Water Act in the United States, the EU Water Framework Directive, and many river health
programs in Australia). The main practical problem is the impossibility of locating such undisturbed sites.
One response is to model the reference state, or attempt to reconstruct it using expert opinion or
historical records. The alternative response is to accept a less stringent definition of reference condition
that is more readily defined (see below).
Minimally disturbed condition, MDC
Accepting that finding truly undisturbed sites is impossible, the best approximation of biological integrity
is minimally disturbed sites. The disturbance at such sites is below the threshold for producing
measurable effects. Once established, the distribution created by a group of sites in MDC will vary little
over time. There is a practical difficulty in finding some, or a sufficient number of, sites in MDC. In some
places that have been settled for a long time, or which have been the subject of intensive development,
there may be no such sites. This is particularly the case for lowland rivers. The SRA (Murray-Darling
Basin) defines reference as the condition that would be likely to prevail now had there been no
significant human intervention in that region (Davies et al., 2008), which equates to MDC. Different
methods are applied in the SRA to estimate reference condition for the various ecosystem components
used to define river health. The AusRivAS system for describing health of aquatic macroinvertebrate
communities in Australia (Simpson and Norris, 2000) is based on the ratio of observed over expected,
where the expected community characteristics are derived from minimally disturbed reference streams.
8
Historical condition, HC
The condition of streams at some point in their history may be an accurate estimator of true RC(BI) if the
historical point chosen is before the start of any human disturbance. However, many other historical
reference points are possible, such as pre-intensive agriculture (EU Water Framework Directive) or pre-
European settlement (as often applied in Australia and the U.S.).
Least-disturbed condition, LDC
Least disturbed condition is associated with the best available physical, chemical, and biological habitat
conditions that can be found under present day conditions. It is ideally described by evaluating data
collected at sites selected according to a set of explicit criteria defining what is ‘‘best’’ (or least disturbed
by human activities), such as a certain maximum percentage of the catchment area under agricultural
land use. The Flow Stress Ranking procedure used to measure the degree of alteration of flows in rivers
in the state of Victoria, Australia (SKM, 2005) finds LDC by ranking every sampled site from least to
most altered.
Best attainable condition, BAC
Best attainable condition is equivalent to the expected ecological condition of least-disturbed sites if the
best possible management practices were in use for some period of time. Sites in BAC would be places
where the impact on biota of inevitable land use is minimized. This is a somewhat theoretical condition
predicted by the convergence of management goals, best available technology, prevailing use of the
landscape, and public commitment to achieving environmental goals (Stoddard et al., 2006). BAC will
never be ‘‘better’’ than MDC, nor ‘‘worse’’ than LDC, but may be equivalent to either, depending on the
prevailing level of human disturbance in a region (Stoddard et al., 2006).
Benchmark corresponding to a previous sampling round
The main interest in a river health program is not necessarily the grade of river health relative to
reference, but more to do with the trajectory of river health – is river health improving or getting worse
over time? This is particularly the case in programs where the rivers are known to be degraded, and
river health monitoring is closely linked to a program of management response. In this situation, the
emphasis in reporting river health would be the change in condition since the previous, or the first,
sampling round. This was recognised by Davies et al. (2008, p. 7) for the SRA of the Murray-Darling
Basin, who noted that “In time, the importance of Reference Condition in SRA assessments is likely to
diminish as the emphasis shifts toward detecting change between successive assessments”.
Benchmark corresponding to established standards or criteria
Assessment of water quality data has long relied on established standards or criteria to judge suitability
for biota, and other river uses. These standards or criteria are typically presented in tabular form,
showing minimum acceptable concentration values for various contaminants or water properties
according to known tolerance limits. The criteria are usually specific to the designated use of the water
body. Similar limits can also be specified for contaminant loads, with an example being the requirement
in the U.S. to calculate Total Maximum Daily Loads (TMDLs) for certain impaired waters as part of
Section 303d of the Clean Waters Act. The TMDL is a calculation of the maximum load of a pollutant
that a water body can receive and still safely meet water quality standards.
The National Water Quality Management Strategy (NWQMS) for Australia and New Zealand (ANZECC
and ARMCANZ, 2000) takes a risk-based approach to assessing the suitability of water quality. Trigger
values are assigned to selected indicators. If data from a test site exceed the trigger value, decision
trees are used to determine if the test values are inappropriately (unnecessarily) ‘triggering’ potential
risk and hence management response. Exceedances of the trigger values are an ‘early warning’
mechanism to alert managers of a potential problem. They are not intended to be an instrument to
assess ‘compliance’. The hierarchy for deriving trigger values for a particular location (from most to least
preferred) are: local biological effects data (e.g. ecotoxicity tests); local reference data (mainly for
9
physical and chemical stressors); and, tables of default values provided in the Guidelines. Trigger
values are provided specific to upland river, lowland river, freshwater lake and reservoir, wetland,
estuary, and marine ecosystem types, and the Guidelines provide trigger values specific to four climatic
regions of Australia and for New Zealand. The triggers based on reference condition are derived
through observations made at reference sites (these could be MDC, HC or LDC – see above).
Under the NWQMS system three categories of ecosystem condition are specified:
High conservation/ecological value systems
Slightly to moderately disturbed systems
Highly disturbed systems
Trigger values are specified for four different protection levels, 99%, 95%, 90% and 80%, with the
protection level signifying the percentage of species expected to be protected by the trigger values. In
most cases, the 95% protection level trigger values should apply to ecosystems that could be classified
as slightly–moderately disturbed, although a higher protection level could be applied to slightly disturbed
ecosystems where the management goal is no change in biodiversity. The highest protection level
(99%) has been chosen as the default value for ecosystems with high conservation value, pending
collection of local chemical and biological monitoring data. The 99% protection levels can also be used
as default values for slightly–moderately disturbed systems where local data are lacking. For
ecosystems that can be classified as highly disturbed, NWQMS recommends use of the 95% protection
trigger values, but in certain cases it may be appropriate to apply lower protection values, as low as the
80% protection values.
While the NWQMS was not specifically designed as a method for reporting river condition (and is not
used as such), the standards established as trigger values could serve as benchmarks from which to
assess relative river condition. The trigger values are similar to the reference conditions described
above, because even if the values were not derived from local reference sites, the default values are
assumed to represent conditions expected at reference sites. The main difference between the
reference condition approach and the trigger value approach of the NWQMS is that the latter accepts
less stringent reference standards for systems that are independently deemed to be disturbed relative to
near natural condition. So, a stream classed as ‘slightly to moderately disturbed’ that meets all the
trigger values for 95% protection level could be said to have the same acceptable level of health as a
stream classed as ‘high conservation/ecological value’ and meeting the trigger values for 99%
protection level.
Aspects of stream health other than water quality can also be benchmarked against established criteria
that are not necessarily sourced from a local reference distribution. One example to illustrate this point
is fish habitat. Koehn and O’Connor (1990) produced a comprehensive book that details the life cycles,
and physical and chemical habitat tolerances and preferences of the native fish species present in the
rivers of Victoria, Australia. The information is based on published data, some of which was derived
from controlled experiments and some from field observations. The observations were not necessarily
made in reference rivers. The information in this book (supplemented by more recent published findings)
has been used in, or has at least influenced, every environmental flows study undertaken in Victoria,
such that the assessment of habitat availability under current conditions, and under any future
conditions with environmental flows implemented, is relative to these published criteria. For example
adult river blackfish are presumed to require water depths greater than 0.2 m and velocities less than
0.2 m/s. These are interpreted as tolerance limits. Using hydraulic models, the amount of available
habitat can be assessed across a range of flow conditions. Environmental flows are then recommended
that will provide an ‘adequate’ amount of suitable fish hydraulic habitat at certain frequencies and
durations (to suit presumed life cycle and behavioural requirements), such that the fish population is
likely to be maintained. The future flow regime may correspond to the recommended regime, but trade-
offs and compromises often mean that it does not. If a time series of undisturbed (reference) flows is
available, and if it can be assumed that the stream morphology has not altered from reference, then the
10
amount of habitat provided by the future flow regime can be compared with reference. However, this is
not always possible, and in most cases the amount of habitat provided by the future flow regime is
compared with the amount provided by the environmental flow regime recommended to maintain the
fish populations at low risk (the derivation of which relied heavily on the criteria sourced from published
literature).
Benchmark corresponding to standards for designated use
Established criteria often exist for water quality whereby each water quality parameter has an
associated range that is appropriate for particular designated use classes. In Australia, the NWQMS
recognises six ‘environmental values’ which correspond to classes of river use:
1. aquatic ecosystems;
2. primary industries (irrigation and general water uses, stock drinking water, aquaculture and
human consumers of aquatic foods);
3. recreation and aesthetics;
4. drinking water;
5. industrial water; and
6. cultural and spiritual values.
Each of the classes of river use has associated criteria (known as triggers in the NWQMS). Under the
NWQMS system, the designated uses are not assigned to particular river reaches but are simply
classes of use that have corresponding water quality guidelines – a particular river reach may have
multiple uses.
The health of waterways in the United States is protected by the Clean Water Act. The purpose of
legislation under the Act is to maintain clean waters (‘drinkable’), to make sure that game fish are safe
for human consumption (‘fishable’), and that waterways are safe for recreation (‘swimmable’). Some
States list agriculture, industry, and navigation among their designated uses.
In China, State of the Environment reporting for river health is based on National Surface Water Quality
Standard (GB3838-2002), which classifies chemical water quality into five water use classes (or grades)
for a range of indices (e.g. MEP, 2006). A number of water quality indicators are used to define these
standards, with each parameter having a numerical limit for each grade (Ma and Ortolano, 2000). The
five grades and corresponding uses are:
Grade I is for water flowing through national nature reserves;
Grade II is for the source of municipal drinking water supply (first grade conservation area),
conservation areas for rare aquatic species, and areas for fish spawning;
Grade III is for the source of municipal drinking water supply with treatment required (second
grade conservation area), conservation areas for common aquatic species, and areas for
swimming;
Grade IV is for sources of industrial use and recreational use other than swimming (e.g.
boating and fishing);
Grade V is for sources of industrial cooling water, irrigation water, and ordinary landscape.
China has two separate water management unit systems: water function zone for Ministry of Water
Resources (MWR) and water environment function zone for Ministry of Environmental Protection (MEP).
The most stringent water quality guidelines apply to aquatic ecosystem protection. In China, the function
zones are spatial units that have designated uses, and corresponding minimum water quality grades
that, if met, would allow the full utilization of the river resource according to its designated use.
11
Benchmark corresponding to management target
In most situations, reference condition is not the management target, either because it is accepted that
this is unattainable regardless of the best intentions of the stakeholder community, or simply because
the process of setting management targets through integration of ecological values with social, cultural
and economic ones gives rise to compromises.
The term “healthy working river” was coined as part of The Living Murray initiative, a process of
assessing the environmental flow needs of the River Murray, Australia (Jones et al., 2002). A similar
concept known as the “living working river” was applied to the Fraser River estuary in Canada (FREMP,
1994). A healthy working river is one that is managed to provide a compromise, agreed to by the
community, between the ecological health of the river and the level of human use. A defensible target
for managing the ecological condition of working rivers is best attainable condition (BAC), which is the
ecological condition that would be achieved under a regime of best management practice for the agreed
type and intensity of catchment land use and river utilisation. BAC could be defined for each designated
use class.
Recommendations: benchmark for expressing relative river condition
4. Most rivers in China, except some headwater reaches in mountainous regions, are disturbed in
some way. Many of the alterations have been in place for centuries or even thousands of
years, particularly in the lowland areas. It will not be possible to define MDC or HC for most
regions. LDC would likely represent a relatively disturbed condition in most places. It is likely
that an alternative to the traditional concept of reference will be required for China.
5. Given the lack of reference sites in China, it may be preferable to set as the benchmark the
best attainable condition (BAC) for the designated river use within existing functional zones. In
the vast majority of cases this will leave room for improvement over current condition. It is
envisaged that the BAC would be independently defined through a scientific process. It would
be a matrix that covered particular river attributes, for any given class of use, scale of river,
geomorphological setting, and eco-hydrological river class.
6. The BAC would not necessarily correspond with the working management targets set to
achieve short-term goals at any particular time, but it would represent an ideal long-term target,
and a consistent set of benchmarks from which to compare like rivers at the national level.
Once a river prioritised for management action achieved the target level of river health, the aim
of management would be to maintain BAC in that river, with rehabilitation resources then
directed to improving the condition of another high priority river. Of course, management
authorities would also have the prerogative of changing river use class, in order to pursue
achievement of even higher levels of stream health.
7. Sites for characterising BAC are unlikely to be available in China. In this case, established
standards or criteria determined using any practical method, with expert opinion likely to be
required, at least in the initial establishment of the matrix.
8. One potential problem with using management targets as the benchmark for river health arises
when the targets are intentionally unambitious in order to give the impression of a high level of
achievement of expected river health. This result may create a superficial and temporary sense
of achievement, but it would provide little motivation to further improve stream condition. It is
important then to adhere to the principle that long-term management targets correspond to a
genuine BAC.
9. Another potential issue with BAC is that continued development of water resources could lead
to an unremarked decline in absolute levels of river health – unremarked because when an
undeveloped river with close to natural stream health targets is developed, its use is simply re-
designated to a lesser class, with less stringent health targets. Thus, prior to, and after, the
development, the river may have met the appropriate health target, but absolute health would
12
likely have declined. Of course, such declines would to some extent be offset by improvements
to stream health achieved in other previously poorly managed rivers. This issue is not so much
to do with the choice of river condition benchmark, but more to do with development and
implementation of appropriate policies concerning water resources development.
Deciding what and how to measure
Components
The hierarchy of measurement in a river health monitoring program begins at the scale of the simplified
ecosystem components and the drivers of ecosystem processes (Figure 2). These components could
also be referred to as themes, or elements of the program. The main components are:
Catchment processes
Instream physical processes (hydrology and geomorpholology), which also give rise to
hydraulic conditions
Water quality and sediment chemistry, which also includes contaminant loads
Aquatic and riparian life, which include flora, fauna and ecosystem processes
The components can be arranged in a rough hierarchy of drivers to responses, but some responses are
also drivers of other processes - the components are linked through physical, chemical and ecological
processes (Figure 2). Habitat is not identified here as a category of ecosystem component, because
habitat requirements and preferences vary a lot between species, and habitat is generated through the
interaction of the other identified ecosystem components. Habitat is included as a component of many
river health programs, particularly in the U.S. (Bain and Hughes, 1996) and Europe (Peterson, 1992;
Environment Agency, 1997; Raven et al., 1997), but the variables being measured are actually aspects
of hydrology, geomorphology, hydraulics, vegetation and water quality.
A program can concentrate on one component, combine a number of components or, for particular
reaches, river basins, or regions, select from a group of program-approved components to suit local
ecosystem conditions, management issues, and available resources. Clearly, the more comprehensive
is the program the more information it generates about the status of river health, the cause of identified
river health problems and how to best manage the river to improve river health. However, apart from the
issue of cost, it may be that some components are not worth including because they lack sensitivity to
likely variability in river health over space and time. This could be because of a high level of natural
variability that cannot be overcome without an unrealistically expensive sampling program, or because
there is currently no policy mandate to address that particular component, in which case improvements
in the condition of that component would not be expected. In development of the SE Queensland
EHMP, from 75 indicators initially tested, 22 from five indicator groups (water quality, ecosystem
metabolism, nutrient cycling, invertebrates and fish) responded strongly to the disturbance gradient and
16 were subsequently recommended for inclusion in the monitoring program. The major field trial
involved 53 sites.
The aquatic and riparian life component (bioassessment) has a strong appeal for inclusion in any river
health monitoring program. The common understanding of river health among the wider community is
related to the apparent vitality of the river (i.e. the extent to which it supports life). Most people already
have a concept of abundance and diversity of biota, so communicating river health in these terms is a
more straightforward exercise than if indirect or more obscure measures of river health are used.
13
Figure 2. Simplified components of river ecosystem condition that can be included in a river health monitoring program. Not all attributes of the ecosystem can be addressed directly by river management.
Measuring the drivers of river health also has appeal because they relate more closely to the sorts of
management actions that are undertaken to improve river health. In this way, the results of monitoring
can be used directly to inform management strategies. Stressors of river health are either driver
variables that have been modified well beyond their natural range, or foreign elements that have been
introduced to the system. Examples are: (i) hydrological stress occurs when too much water is extracted
from, or too much water is added to, a river, modifying the pattern of flows (as opposed to natural
hydrological stress, which occurs at times of naturally very high and low flows), (ii) stress from nutrients
occurs where nitrogen and phosphorus levels are enriched by inflows of sewerage or agricultural runoff
(as opposed to the natural levels of phosphorus and nitrogen in a river, which is critical to normal
functioning), (iii) contaminants introduced to a river that were never present in the natural state, such as
might be present in outfalls from certain industries, and (iv) exotic biota, such as fish and plants from
other countries or other river systems that would not naturally be present and which become a pest in
their new environment.
Catchment processes:geology, rainfall; evapotranspiration; runoff;
land use; land cover; sediment generation and transport; contaminant, carbon and
nutrient generation and transport
Hydrology:river flow pattern and
magnitude; wetland hydrology; groundwater-surface water
interactions
Physical form and process:
process of sediment mobilisation, transport and deposition that creates physical template of
habitat for biota
Driver
ResponseFlora:
instream, riparian and wetland plants
Fauna:instream, riparian and wetland invertebrates, fish, birds, amphibians,
molluscs, mammals, etc.
Aquatic and riparian lifeabundance, organisation (diversity, species composition, food webs), recruitment (age
structure), processes
Hydraulics:interaction of hydrology and
physical form creates pattern of hydraulic habitat –water
connectivity, extent, depth, velocity and shear stress, in channel and on floodplain
Ecosystem processes:
rates of community metabolism
(production/respiration), nutrient cycling
Microorganisms:bacteria, cyanobacteria, algae, fungi, protozoa,
viruses
Red font indicates aspects of rivers that are practical for active management to maintain good, or improve impaired, river health:• Health is the river condition relative to a benchmark or reference condition• Impairment is due to human pressures
Water quality:temperature, nutrients, acidity,
salinity, dissolved oxygen, turbidity, faecalcontamination,
metals, toxins, carbon
Sediment chemistry:
nutrients, contaminants, salinisation, acid sulphate
Elements of River Condition
14
Interpreting the results of a bioassessment program in terms of management (i.e. diagnosis) relies on
having good knowledge of the way the biotic variables vary with the various driver disturbance
gradients. This is not always the case, which means that either the driver/stressor variables need to be
included in the river health monitoring program, or cause-effect is investigated as a separate exercise.
For a particular river, it may be the case that through historical data, or casual observation, the main
cause of river health decline is obvious. This would apply to pressures such as untreated sewerage
discharge, or industrial waste discharges. Simply measuring some aspects of sensitive biota, and/or the
relevant water quality indices will provide a good characterisation of the extent and severity of the river
health problem. Communication of this information may be critical in achieving the desired management
responses, even though the problem and solution was largely known prior to monitoring. However, this
pragmatic approach could fail to achieve real improvement in river health if the impairment was a multi-
layered problem. For example, achievement of water quality targets may have little consequence for the
diversity and abundance of biota if one or more other components of the system are also impaired, and
they simply take over the role of limiting factor.
The above discussion suggests that when considering what components to include in a river health
monitoring program there are three choices:
1. At the outset, design the program as a comprehensive one that includes driver/stressor and
response components, test the utility of a large number of variables in pilot studies, and then
trim the list to the most effective variables.
2. Begin with a bioassessment program that is limited to the most promising response variables
(selected on the basis of what is known of the rivers proposed for monitoring, and those proven
in the literature), then periodically review the program and add driver/stressor components as
necessary, or
3. Commit to a bioassessment-only program, and gather information on the drivers/stressors of
river health under a separate program.
Variables, data, metrics, indicators and indexes
Characterising an ecosystem component requires selection of some aspect of the component, and then
measuring it to create data. While these raw data may be understandable to scientists, river health
monitoring requires that the data are modified into a form that (i) allows condition to be expressed
relative to a benchmark, and (ii) is understandable to the intended audience (principally the general
public, river managers and policy makers). Suggested terminology for the numerical aspects of river
health monitoring is (after Davies et al., 2008):
Variable: a characteristic of the ecosystem that is measurable
Primary data: the observed value when a variable is measured
Derived data: secondary values calculated from primary data, but still constituting a measure
of the variable
Metric: the difference between the observed data value and its estimated value under
benchmark or reference conditions.
Indicator: a value derived by integrating two or more metrics
Index: an integrated value for stream health, derived by integrating two or more indicators and
aggregated for reporting
Choosing a suite of variables to measure is a challenging aspect of river health monitoring program
design. Norris and Hawkins (2000) listed six generally agreed characteristics of effective river health
indicators:
1. quantify and simplify complex ecological phenomena;
15
2. provide easily interpretable outputs
3. respond predictably to damage caused by humans while being insensitive to natural spatial or
temporal variation;
4. relate to an appropriate scale;
5. relate to management goals; and
6. be scientifically defensible
Similarly, the US Environmental Protection Agency has established a list of suitable criteria for
ecological monitoring programs (EMAP) (Jackson et al., 2000). The criteria for selecting variables and
indicators are organized within four evaluation phases:
Phase 1: Conceptual Relevance:
Is the indicator relevant to stream health?
Phase 2: Feasibility of Implementation:
Are the methods for sampling and measuring the variables technically feasible, appropriate,
and efficient for use in an on-going assessment program?
Phase 3: Response Variability:
Are human errors of measurement and natural variability over time and space sufficiently
understood and documented that they can be managed and/or taken into account?
Phase 4: Interpretation and Utility:
Will the indicator convey information on river condition that is meaningful to stakeholders and
decision-makers?
In designing a river health monitoring program for China it is recommended that all proposed variables
and indicators be evaluated using the EMAP criteria.
There are many different standard ways to measure the selected ecosystem components. The most
expedient approach would be to adopt protocols that have proven successful elsewhere, but it is likely
that adaptation will be required to suit local conditions. A review of various approaches is provided in
Gordon et al. (2004). Bioassessment is included in most stream health assessment programs because it
addresses directly the issue of ecological health. The condition of the biota is an integrative measure of
the impacts of all of the stressors on the stream. Also, bioassessment is required by legislation in many
parts of the world. On the other hand, there is little scope to directly manage the biota (although fish
stocking, and pest species containment are notable exceptions), and it is not always a simple matter to
diagnose the cause of observed poor condition of the biota – it may not be obvious which management
actions will be most effective in improving the condition of the biota. If the stream health monitoring
program is closely linked to management, then there is a strong rationale for including driver/stressor
variables.
More than one hundred different bioassessment methods exist in Europe, two thirds of which are based
on macroinvertebrates (Rosenberg and Resh, 1993; Verdonschot, 2000). Macroinvertebrates are
popular because they are found in most habitats, they have generally limited mobility, they are quite
easy to collect by way of well established sampling techniques, and there is a diversity of forms that
ensures a wide range of sensitivities to changes in both water quality (of virtually any nature) and
habitats (Hellawell 1986, Abel 1989).
Fish are popular bioindicators because they are known to be sensitive to water quality, they are known
to have characteristic habitat preferences, are relatively easy to sample and identify in the field, and
they tend to integrate effects of lower trophic levels; thus, fish assemblage structure is reflective of
integrated environmental health (Barbour et al., 1999). As they have a relatively large range, fish are
16
best suited to assessing macrohabitat and regional differences. They are long-lived, so fish can
integrate the effects of long-term changes in stream health.
Benthic algae are useful ecological indicators because they are abundant in most streams, because
they respond rapidly to changed conditions, are relatively easy to sample, and their tolerance to
environmental conditions is known for many species. Periphyton have been widely used as bio-
indicators in Europe, where many different approaches have been used for sampling and data analysis
(Whitton et al., 1991). Some phytoplankton and periphytic algae have been shown to have very narrow
tolerance ranges of pH, and diatoms have been used to indicate acidification in rivers (Coste et al.,
1991).
Community metabolism refers to the biological transfer of carbon, and involves measurement of the
basic ecological processes of production (via photosynthesis) and respiration (Bunn and Boon, 1993;
Bunn et al., 1999). Community metabolism is sensitive to small changes in water quality and riparian
conditions, including light inputs, and may enable early detection of an impact before it is manifest in
changes in organism assemblages. The P/R (Gross Primary Production: Respiration) ratio is considered
a key biological indicator of system health. Unimpacted streams are typically heterotrophic (i.e. P/R<1)
and therefore are a net consumer of carbon. Davies (1997) showed that impacted sites typically have a
P/R ratio >1 (autotrophic), indicating a fundamental shift in the energy base of the ecosystem. A shift
from heterotrophy to autotrophy can indicate catchment disturbance and/or nutrient enrichment.
There are a number of ways to calculate metrics, indicators and indexes. Methods can be drawn from
published literature. There is debate in the literature over the relative merits of predictive versus
multimetric approaches (Norris and Hawkins, 2000). Examples of predictive models are AusRivAS
(Simpson and Norris, 2000), used nationally in Australia and RIVPACS (Wright, 1995), used nationally
in the United Kingdom. Multimetric approaches are very common in the U.S. (e.g. Barbour et al., 1999),
particularly for water quality monitoring programs (Southerland and Stribling, 1995).
Predictive models quantify river health as the degree to which a site supports the biota that would be
expected to occur there in the absence of alteration by humans. Measurements compare the
composition of biota at reference sites and test sites. The models are derived from data collected from a
network of reference sites (MDC or LDC). A measure of degradation is then obtained by observing (O)
the taxa at a site, comparing them with the taxa that the predictive model expects (E) to find there, and
expressing the deviation as a ratio (O/E). Loss of taxa is a fundamental measure of biological
degradation because taxa represent the basic units from which higher levels of biological organisation
are abstracted (Norris and Hawkins, 2000).
The multimetric approach attempts to quantify the concept of biological integrity by giving values
(indices or metrics) to several different biological attributes and comparing them to the values expected
to occur (Norris and Hawkins, 2000). An overall measure of biological integrity is then obtained by
aggregating values of the individual indicators. Sampling of reference sites generates expected values
for each indicator. Whereas predictive models utilize a single measure (taxonomic composition),
multimetric approaches include information from several levels of biological organization. Norris and
Hawkins (2000) were of the view that simpler is better unless a compelling argument can be made for a
more complicated approach.
The multimetric approach is not the same as the holistic approach. The holistic approach develops
indices for a range of components, one of which is the biota. That indicator might be calculated using a
predictive model or a multimetric approach. For example, the Index of Stream Condition (Victoria)
(Ladson et al., 1999) combines indicators on water quality, physical form, streamside zone (vegetation),
hydrology and aquatic life. In SE Queensland the Ecosystem Health Monitoring Program (EHMP)
measures 18 indicators within five groups: physical/chemical, nutrients, ecosystem processes, and
invertebrates. The aquatic life indicator of the ISC and the invertebrate indicator of the EHMP are both
based on the AusRivAS predictive model.
17
A critical aspect of the design of a monitoring program is sampling. It is necessary to minimize Type I
errors (incorrectly classifying an unimpaired site or reach as impaired) and Type II errors (incorrectly
classifying an impaired site or reach as unimpaired). This is a matter of deciding on the appropriate
variables, measurement methods, number of and location of sample sites, frequency of sampling,
quality control and quality assurance protocols.
Selecting variables that relate to manageable aspects of rivers
If river health monitoring is to be closely linked to management responses, it could be argued that the
program should be based around the types of management responses that are feasible, or mandated
under current policy (Table 2).
Not all aspects of rivers can be actively managed to achieve positive river health outcomes (Figure 1).
For example, while riparian re-vegetation is a popular choice for management response, other aspects
of biota are less open to direct management. Direct management of physical form is common practice
(through channel rehabilitation, and sediment control), which could be grounds for including geomorphic
attributes. Hydrology is already measured through stream gauging networks, so its inclusion would not
impose a high cost on the program. This is especially relevant because one of the expected actions to
improve river health is provision of environmental flows. One potential problem with hydrology is the lack
of gauged reference data, so the benchmark may have to be modelled. A water quality monitoring
network is established throughout China, and this would be a logical starting point for any river health
monitoring program, especially when poor water quality is known to be the major factor limiting stream
health in many areas, and is being aggressively managed.
Some ecological assets have particular requirements that need to be taken into account when designing
a river health monitoring program. For example, the defining feature of many Ramsar listed wetlands is
high abundance and diversity of birds, and perhaps presence of rare or endangered species. Although
birds may present some practical difficulties for monitoring, there may be an obligation to include this
aspect of the biota in the program.
Monitoring environmental flows
Two types of monitoring are appropriate for environmental flows:
Compliance monitoring to determine if the environmental flow rules were followed (i.e. were the
environmental flows delivered to the river as specified)
Routine monitoring to test the hypothesis that environmental flows will lead to improved river
health (i.e. did river health improve as expected in response to the implementation of
environmental flows?)
The hydrological compliance monitoring is relatively straightforward and simply involves measuring river
flow at gauging stations within reaches where environmental flow rules have been set. Compliance can
be expressed as a percentage value using the methodology described in Gippel et al. (2009). In this
method, the scientific panel expresses the environmental flow rules in terms of event magnitude,
duration, frequency and rate of rise and fall, and baseflow magnitude and duration. Not all events are
expected to occur every year, so another important dimension is the inter-annual frequency of events,
which means how many events should occur in sequences of years of a given length (e.g. 5 events in
every 10 year sequence). The hydrological compliance of some environmental flow components can be
checked annually, while others can only be checked over a series of years.
In monitoring environmental flows, hypothesis testing refers to a number of ‘predictions’ or ‘questions’
that are to be tested. For any particular river, the foundations of the hypotheses to be tested can be
found in the environmental flow assessment documentation. Of course, this assumes that the
environmental flows method being used is one based on a conceptual understanding of the flow-
ecosystem relationships, as opposed to one based on simple hydrological rules of thumb. Each
environmental flow component will relate to an ecological or geomorphological objective, which defines
18
the environmental values to be protected or enhanced. The monitoring program must first define
measureable ecosystem targets or outcomes that are believed to be casually related to these values.
The hypotheses should relate to expected short-term and long-term responses (Cottingham et al.,
2005a; 2005b).
The design of a program to monitor environmental flows must accommodate flow-related objectives for
biota known to have differing dependencies on flow, yet for practical reasons only a limited number of
monitoring sites can be used (Roberts and Dyer, 2007). Roberts and Dyer (2007) suggested selecting
monitoring sites and variables on the basis of the expected response magnitude.
Where environmental flows can be treated as a management experiment, and before-intervention data
and/or spatial control rivers are available, BACI (Before After Control Impact) designs will allow testing
of predictions about ecological responses to environmental flows more formally, and provide greater
confidence when inferring a causal link between responses and environmental flows (Cottingham et al.,
2005a; 2005b).
A lack of control locations and limited opportunity for collecting before-data will often preclude the
adoption of a BACI design. The best alternative option would be to evaluate whether or not predictions
associated with the relevant environmental flow objectives are realised (termed objective/prediction
assessment). For some reaches and objectives, reference (comparison) locations can provide points of
comparison (Cottingham et al., 2005a; 2005b).
A regression-based approach describes a mathematical relationship between variables based on the
data available. This is in contrast to BACI type designs that explicitly test for differences between two or
more data sets. Cottingham et al. (2005b) provided an introduction to Bayesian Hierarchical Statistics
(BHS) and its possible application to monitoring of environmental flows. Chee et al. (2006a; 2006b)
advocated the use of a regression-based approach within a Bayesian hierarchical modelling (BHM)
framework. This approach may have certain advantages with regards to the inclusion of data from
multiple, partially different, sites within a single analysis. It will also allow the inclusion of prior
knowledge of the effects of flow on the biota to be formally incorporated in models (Chee et al., 2006a;
2006b).
Additional short-term ecosystem studies should also be considered to support an environmental flow
monitoring program and provide information to assist with environmental flow recommendations in the
future (Cottingham et al., 2005a; 2005b). These studies would aim to fill gaps in fundamental knowledge
about relationships between aspects of the ecosystem and aspects of the flow regime.
Cottingham et al. (2005b) recommended that discussion of effect size and statistical power will be
necessary when finalising the monitoring study design and agreeing on the monitoring effort (sampling
intensity). Specialist statistical advice should be sought so that the implications of decisions on effect
size and interpretation of results can be considered.
19
Table 2. The links between pressure and response in river management.
Human activities (Pressure) that potentially impair river health (Condition)
Potential mitigation measures (Response)
Hydrology
Regulation of flow pattern and volume by dam
- Hydropower operation Environmental flow rules
- Water storage Environmental flow rules
- Water transfer Environmental flow rules, cap on extraction
Flow volume change
- Pumping from river Set allocations, meter extraction, water trading
- Groundwater pumping Cap on extraction, regulate
- Diversion from river Environmental flow rules
- Farm dams Cap on development
- Land use choice (forest v pasture) Manage re-forestation for hydrology
Physical form/sediment transport processes
Sand/gravel extraction Regulate and enforce
Gold mining Regulate and enforce
Channelisation Physical rehabilitation
Channel diversion Physical rehabilitation
Lateral barriers (levees, dykes, embankments) Partial removal (increase connectivity)
Longitudinal barriers (weirs, dams, culverts) Fishways (increase connectivity)
Reduced catchment sediment supply
- Trapping by dam Sediment nourishment, bed stabilisation, wait for adjustment
- Catchment sediment control Sediment nourishment, bed stabilisation, wait for adjustment
Accelerated catchment sediment supply
- Poor land management (gullying, cultivation)
Soil conservation, sediment trapping, sediment transporting flows, sand extraction, wait for adjustment
Low mobility/homogeneity of channel
- Hardlining bed and banks Physical rehabilitation
Accelerated mobility of channel (bank erosion, channel migration)
- Disturbance of riparian vegetation Re-vegetation, fencing, artificial bank stabilisation
Water quality
Sewerage outfall Sewerage treatment
Industrial effluents Legislation, compliance checking
Irrigation return flow Seek water savings
Direct channel disturbance (stock/sand and gravel extraction)
Fencing/regulation
Land use practices (non-point source pollution, salinisation)
Catchment management
Sediment chemistry
Sediment contamination Manual removal, flushing flows
Aquatic and riparian life
Spread of exotic species Appropriate containment or eradication method
Over-fishing Regulate and enforce
Low fish diversity/abundance Fish re-stocking
Poor extent and quality of riparian/wetland vegetation
Re-vegetation
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Recommendations: what and how to measure
23. This report does not recommend a suite of indicators that should be included in a river health
monitoring program for China. It may be necessary to evaluate a broad range of indicators
(selected after first assessing them against US EMAP criteria) in pilot studies, and then select
those that best respond to known disturbance gradients. If expediency is required, then
bioassessment using a small number of indicators known from the literature to be sensitive to
the form of water quality impairment typical of China’s rivers would be the best starting point.
24. Assessment of environmental flows involves two components: hydrological compliance
monitoring, and hypothesis-based ecological/geomorphological response monitoring.
Practicalities will often mean that a BACI (Before After Control Impact) program design is not
possible, but other designs can also be effective. It will be necessary to judiciously select
variables and sites, with a focus on monitoring those variables or sites where the expected
response magnitude is large.
25. Whatever indicators are chosen, it is critical that the river health monitoring program follow
rigorous scientific protocols in selecting sites, determining sampling frequency, field sampling
and measurement, laboratory measurement, and statistical analysis. The expedient approach
is to adopt proven standard methods.
River Health Assessment and Reporting
While river health monitoring is concerned with data generation, river health assessment is concerned
with analysis and interpretation of those data. The assessment provides information that aids
management decisions. The products of the assessment are reports that interpret the results of
monitoring in the context of the objectives of the program, show spatial distributions, analyse for trends
in the data, and attempt to explain the results in terms of the causative factors. It is likely that the
assessment process will draw on data and information from sources external to the river health
monitoring program. For example, if river health driver/stressor variables are not monitored within the
program, then explanation for the patterns in the biological data will have to draw on whatever
contextual information is available.
Obtaining contextual or explanatory information to help interpret
river condition data River condition data can defy confident interpretation in terms of causative factors, because of
confounding influences (too many possible causes operating at the same time and place). Despite this,
establishing broad associations between cause and effect may be adequate to suit the objectives of the
program. Information on drivers of river health, and the extent to which these have been altered, can
exist independently of the river health monitoring program. Examples are records of river management
works completed, and sewerage completion. Land and water management agencies usually hold
databases concerning relevant aspects such as land use, soils, population, dam location and operation,
rainfall, runoff, fisheries, tourism, and water utilization. The Global Water System Project (GWSP) of the
Earth System Science Partnership (Alcamo et al., 2008) has developed global datasets (gridded maps)
of various parameters (http://atlas.gwsp.org/) that may aid interpretation of river health data.
Reporting and communication Regional or provincial-level river health monitoring programs are likely to vary in many respects
throughout China. It will still be possible to report at the national scale provided the programs have
some basic aspects in common. One important consideration is that the benchmark or reference
condition should be consistent. Also, if the indexes are reported over the same measure scale (e.g. 0 –
21
1 or 0 – 100), regardless of the variables and data measured, then it is reasonable to compare the
values of river condition from place to place. This simply requires standardization of the index values.
The details of how the results of stream health monitoring are reported should be based on the
objectives of the program (Table 1). One of the key communication outputs is the report card. For
example, the EHMP in SE Queensland reports river condition in an annual report card format, giving
ratings of A to F for each reporting area, a score for overall river health, and one for each of the five
component indicator scores. Scores achieved through time are also displayed in the report card. The
relative condition of each reporting area is indicated by its ranking compared to other reporting areas in
SE Queensland. Text is also supplied to interpret the data and highlight major issues. Most river health
monitoring programs in Australia have adopted a similar style of presentation.
Given the relatively poor condition of many Chinese rivers, consideration will need to be given to how
results are reported to ensure that:
The reporting process gives an accurate picture of river health
Benchmarks are not set too high, such that all rivers are classed at the lower end, with the
potential to reduce incentives for improvement and to distinguish between different levels of
health
Reporting is sufficiently sensitive to show where improvements have been made, even though
the overall condition may remain poor
Reporting recognises national management objectives, including water quality requirements
associated with designated water function zones
To achieve this, it may be appropriate that report cards include information related to a number of
benchmarks, including:
Best attainable condition
Requirements consistent with the relevant water function zone
Changes in condition relative to the previous year
Recommendations: assessment and reporting 26. It is important to interpret the results of the monitoring to match the objectives of the program.
The findings should be reported using a range of formats, to a range of audiences.
27. One of the key products should be report cards, ideally produced annually.
28. The basic reporting unit should correspond with the established water function zones. These
are currently used for water quality reporting. Depending on the distribution of these zones, it
may be necessary to aggregate zones to cover larger areas.
29. It may be appropriate for report cards to include information related to status against a number
of benchmarks. These may include BAC, achievement of water function zone requirements,
and condition relative to previous years.
River Health Application
Application of the results of river health monitoring occurs when actions are taken in response to the
assessment. One way of formally linking river health monitoring data with actions to improve river health
is the Pressure – State – Response (PSR) model.
The PSR model was developed by the Organisation for Economic Cooperation and Development
(OECD 1993). The PSR model provides for the organisation of information on the state (condition, or
health) of aspects of the environment (including rivers), human pressures affecting the natural
22
environment, and the societal responses to address the pressures and environmental issues. The
information of pressure, state and response is captured through the use of indicators. This basic model
was adopted by Australia for State of the Environment (SoE) reporting in 1996 (ASEC, 2001); it is also
termed Condition – Pressure – Response (CPR) model (OCSE, 2007) (Figure 3).
An extension of the PSR model is the Driving forces – Pressure – State – Impact – Response (DPSIR)
model (EEA, 1999), which is used in the Victoria (CES, 2005). This model incorporates Driving forces,
which are the underlying causes of activities that affect the environment, and Impacts, which represents
the effect of changes in environmental quality on the functioning of ecosystems and human health
(Figure 4). The PSR, CPR and DPSIR models offer a framework through which to document cause-
effect relationships and interrelationships between the factors associated with environmental condition.
Rissik et al. (2005) developed a further extension of the PSIR framework (Driving forces were not
included) called the Vulnerability – Pressure – State – Impact – Risk – Response (VPSIRR) model and
applied it to estuaries. This approach includes indices to characterise the vulnerability of the system to
each of the pressures. A risk assessment process is included, whereby risk is a combination of pressure
and vulnerability. The level of risk is compared against the appropriate condition variable to assess
whether the condition of the estuary is the result of its high risk value or whether it is a natural
phenomenon. The framework of Rissik et al. (2005) is issues- and value-driven. Issues and values of
stakeholders and the community are defined and used to determine stressors. Stressors are defined as
the variables which lead to the issues of concern to the community. Stressors in turn can be used to
identify pressures, which are measured using indices. A similar approach was suggested by Arundel et
al. (2008) for developing report cards for the health of Victorian estuaries, with the condition data used
to identify, and score the condition of, assets in particular. The risk from threats (pressures) is focused
on the identified assets.
The Stream and Estuary Assessment Program (SEAP) aims to assess the condition of aquatic
ecosystems throughout Queensland. This will be achieved in the context of Pressure – Vector –
Response models (Marshall et al. 2006a). In this model, the biophysical conditions that are modified by
pressures are termed vectors, and they influence ecosystem responses (Note: the word ‘response’ has
a different meaning here compared to the OECD model). The pressures were grouped into six broad
categories: land use; water use; urbanisation; harvesting and translocation of biota; recreation and
tourism; and landscape management. These pressures influence riverine condition through vectors
such as suspended and deposited sediments, habitat removal and disturbance (riparian and instream),
altered flow volume, timing and variability of flow, pest species, nutrients, toxicants, organic matter,
salinity, pathogens and thermal alteration (Coysh et al., 2007). In order to understand aquatic
ecosystem function at the state (i.e. Queensland) scale it was necessary to categorise aquatic
ecosystems into more homogeneous units. This was done geographically because a geographic
categorisation, or regionalisation, also suited management needs (Department of Natural Resources,
Water, 2006). The regionalisation divided Queensland aquatic ecosystems into nine Freshwater
Biogeographic Provinces explaining how Queensland’s aquatic ecosystems respond to particular
human activities.
23
Figure 3. Condition – Pressure – Response model for State of Environment Reporting adopted for Australia in 2001. Source: ASEC (2001).
Figure 4. Driving forces – Pressure – State – Impact – Response model for State of Environment Reporting. Source: modified from EEC (1999).
Driving Forcessocio-economic driving
forces influencing environmental change
(e.g. population growth, climate change)
PressuresHuman activities causing
stress (e.g. dams, diversion,
channelisation, sewerage outfall)
ConditionState of the environment
(e.g. river health)
ImpactsEffects of environmental
degradation (e.g. biodiversity loss)
ResponsesEfforts to mitigate (e.g.
implement environmental flows)
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Recommendation: application 30. Application involves linking the monitoring program to policy. A mechanism needs to be in
place for transferring the results of monitoring to the agencies responsible for management
actions.
Ecological Assets and River Health Monitoring
Definition of ecological assets River health monitoring is not value-free. Subjective decisions have to be made with respect to what
variables will be measured, where they will be measured, and how the data will be reported. These
decisions are conditioned by the objectives of the program. Issues-based measurement and reporting of
river health is aimed at managing identified threats or pressures, such as salinity, riparian vegetation,
pest-species, or fish passage (State of Environment reporting typically is issues-based). The ecological
asset-based approach to management focuses on protecting key assets, usually particular
independently defined sites of high conservation value. A process-based approach to management
focuses on maintaining or restoring the physical, chemical and biological processes that sustain
ecological assets. Examples are nutrient cycling, water flows, hydraulics, sediment dynamics, dispersal,
adaptation, disturbance, and functional interactions.
Although the term “ecological asset” often appears in the policy literature, few authors provide a precise
definition of this term. The following definitions suggest that the identification of an ecological asset
relies heavily on how much the community values it, and whether it serves a utilitarian purpose (such as
ecosystem services). These definitions do not limit the definition of an ecological asset to a geographical
space (a bounded site), but also allow processes, habitats and organisms to qualify as ecological
assets:
An ecological asset is “an attribute of a natural ecosystem that the community values and
wants to see protected… The term value (or ecological value)…refers to the specific reasons
an asset is considered important. An asset can have multiple values, which can be vastly
different for different stakeholders.” (van Dam et al., 2006).
“An ecological asset is a highly valued component of the environment…an ecological asset is
defined as a species, biological function or place of value... Ecological assets are used as
indicators of an ecosystem.” (DERM, 2009).
“An ecosystem may be considered as a unit within which an assemblage of living organisms
interact with each other and with the chemical and physical environment…The ecological
processes that contribute to ecosystem services…are referred to as ecosystem functions. The
habitats and organisms that give rise to the ecological processes are usually described as the
ecological assets, and these can be protected to ensure ecosystem services are maintained.”
(POST, 2007).
While no consistent and clear definition of ecological assets has yet emerged in the literature, it is
commonplace for policy documents to refer to “key” or “significant” ecological assets. The reason for
defining a high-value sub-set of ecological assets is to allow prioritization of investment in management
of rivers. The prioritization process is one of risk assessment (risk = likelihood x consequence), whereby
the level of threat to each identified key ecological asset is assessed as a “likelihood” and a measure of
river health is used to quantify “consequence” (with close proximity of river condition to reference
condition being a surrogate for high consequence if the asset is lost or impaired).
Schofield (2009) limited the definition of ecological assets to “sites”, with identification of “key ecological
assets” initially based on a site being listed through one of six mechanisms:
25
1. Wetlands of international importance (Ramsar wetlands)
2. Nationally important wetlands
3. A nationally listed threatened aquatic ecological community
4. Places on the Commonwealth heritage list
5. Wild Rivers nomination under legislation
6. Riparian environments of significant conservation value
Also, Schofield (2009) undertook a preliminary assessment of specific ecological assets through a
workshop process using draft HCVAE (High Conservation Value Aquatic Ecosystems) criteria.
HCVAEs (SKM, 2007) include rivers, wetlands, floodplains, lakes, inland saline ecosystems and
estuaries. Aquatic ecosystems with high conversation values are those recognised through the following
mechanisms (Australian Government, 2008):
1. Ramsar Convention,
2. United Nations Convention on Biological Diversity,
3. World Heritage Convention,
4. Japan Australia Migratory Bird Agreement,
5. Bonn Convention on Migratory Species of Wild Animals
6. China Australia Migratory Bird Agreement.
Core environmental values that are considered in identifying a HCVAE are (Australian Government,
2008):
its international recognition
its representativeness as a particular type of aquatic ecosystem
the diversity of species
its distinctiveness
the critical habitat it provides
its ability to demonstrate the evolution of Australia's landscape of biota
the naturalness of its ecosystem
HCVAEs selected for investment in 2009-10 through the Caring for our Country program were identified
by state and territory agencies as having clearly defined threats to their ecological values and good
prospects for recovery (Australian Government, 2008). Threats to HCVAEs were listed as physical
modification or encroachment, loss of biodiversity, pollution and increased nutrient input, changes to
water regimes, utilisation of resources, and the introduction of invasive species (Australian Government,
2008). In selecting sites for investment in 2009-10, priority was given to aquatic ecosystems under
threat from pest plant or animal species (Australian Government, 2008).
The Victorian River Health Strategy (DNRE, 2002) defined three classes of river-related assets:
environmental, economic, and social. The environmental assets included:
the presence of rare species and/or communities and geomorphological features;
sites of significance;
areas with high levels of naturalness of components of the river system including whether the
river or a major river reach meets the criteria for ecologically healthy; and
representative rivers
26
Representative rivers are those in an ecologically healthy condition that can be used to represent the
major river classes that once occurred naturally across Victoria.
Relevance of ecological assets to river health monitoring The concept of ecological assets and key ecological assets are most relevant at the stages of river
health program design, and utilization of program results to river management. If the main objective of a
river health monitoring program is to inform management of independently defined ecological assets
(sites or processes), then the monitoring only needs to be undertaken at the relevant sites or where the
processes of interest occur. Alternatively, the monitoring might be used to help identify the ecological
assets, the risks to those assets, and thus where investment in resource management would be most
effectively directed. For a national level program, the latter approach would be the most appropriate, as
knowledge of the relative value and location of ecological assets is likely to be incomplete and uncertain
at the national-scale.
A liberal definition of ecological asset is appropriate, including biodiversity, threatened species, native
species, species of high conservation value, certain habitats, certain ecological processes, and certain
places. This definition does not limit the design of the river health monitoring program. Where ecological
assets have been identified locally, then it makes sense to consider including them in a river health
monitoring program. This is because these assets are likely to receive most management attention, and
because they are likely to hold high levels of community interest.
Recommendations: ecological assets 17. A liberal definition of ecological asset is appropriate, including biodiversity, threatened species,
native species, species of high conservation value, certain habitats, certain ecological
processes, ecosystem services and certain places.
18. River health monitoring can be used to help identify ecological assets, the risks to those
assets, and thus where investment in resource management would be most effectively
directed.
Stakeholder engagement
Role of stakeholder engagement According to International Association for Public Participation, public participation involves five
elements, which are Information, Consultation, Involvement, Collaboration and Empowerment (IAP2
2007). Public participation is a means of achieving:
Participatory democracy (e.g. community empowerment and providing the opportunity to
develop knowledge for making informed choices)
Transparency in decision-making process
Community empowerment and support
Reduced conflict over decisions between decision-makers and public groups, and between the
groups
Maintaining communication with stakeholders at key points throughout the development and
implementation of a river health monitoring program helps to provide meaningful dialogue between the
public and managers. Providing information in a variety of formats and on specific topics helps the
public to provide input on their special interest issues. It is important that public participation processes
be tailored to suit the specific requirements of the process or activity, and that participants are clear of
their role and influence in process. Effective participation cannot be achieved by simply adopting a
27
successful model from another context. Lastly, public participation needs to be designed and informed
by key principles and be sensitive to relevant local institutions and governance arrangements.
Elements of stakeholder engagement A separate discussion paper and framework on stakeholder engagement and public participation is
being prepared as part of this project. Key elements that the framework will need to address include:
Who are the relevant stakeholders – these may include different levels of government, different
government agencies, industry representatives, civil society, and the broader community
The objectives of stakeholder engagement. These may include using stakeholder views and
values to guide the development process, increasing transparency, reducing conflict over
government decisions, and generally increasing support for the program – and thus its likely
success during implementation,
The relevant times at which stakeholder could, and should, be engaged in the process. This
may include:
o In the identification of key ecological assets
o In determining the objectives and benchmarks for a river health monitoring program
o In determining what information should be collected, and what should be reported and
how
o In deciding and implementing management responses
The mechanisms for engaging stakeholders. Options may include:
o Broad public communication
o Opportunities for public submissions on proposed methods or recommendations
o Formal responses to any submissions
o Public meetings
o Targeted stakeholder meetings
Recommendations 19. Development and implementation of a river health monitoring program should be supported by
a framework for engaging stakeholders at appropriate stages during the process.
Capacity required for implementation
Implementation of a river health monitoring program can require the development of new skills amongst
staff in the responsible institutions. This may include:
The skills necessary to develop an appropriate monitoring river health program
The skills necessary to collect samples, in accordance with the specified protocols
The skills necessary to analyse and interpret the data collected and make recommendations
based on the results
Recommendations 20. The skills required to implement any monitoring program, and the feasibility, time and cost
involved in training relevant staff in those skills, should be a consideration in designing an
appropriate program.
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River Health Monitoring in Australia
National Framework for the Assessment of River and Wetland
Health (FARWH) The National Framework for the Assessment of River and Wetland Health (FARWH) is being developed
as part of the Australian Water Resources 2005 (AWR, 2005) project being undertaken by the National
Water Commission (the Commission) under the National Water Initiative (NWI) (Norris et al., 2007).
The FARWH proposes six key components for the assessment of river and wetland health:
catchment disturbance
hydrological change and spatial extent of wetland and temporal change
water quality
physical form
fringing zone
aquatic biota
The FARWH allows nationally comparable assessments of river and wetland health to be made. This
enables states and territories to include data that are already being collected. The framework does not
prescribe which indices should be selected to represent the six components. The framework
recommends that indices should be:
relative to a reference (usually pre-European conditions)
linear and range standardised to 0 – 1, in increments of 0.1
divided into condition bands
At the scale of an individual surface water management area (SWMA), at least 5 percent of the
recognised river reaches or wetlands should be represented in the monitoring sample.
FARWH is a national approach to reporting river health in a consistent way, but it is not a fully integrated
monitoring program. FARWH relies on obtaining data from existing programs being run by state
agencies. These programs were not established with the requirement for consistent national reporting in
mind, so there will be issues with comparability of data from different sources, and lack of data from
unmonitored areas, or areas where the data are not compatible with the basic requirements of FARWH.
Aspects of methods used by jurisdictions in Australia
Benthic macroinvertebrates
Benthic macroinvertebrates are the most comprehensively monitored indicator in Australia, with each
jurisdiction having one or more active programs. All jurisdictions use the original AusRivAS or a modified
version. The method of sampling design and site selection varies, as does frequency of sampling (twice
yearly to every five years). The least disturbed sites concept is used to define reference in each case.
Most programs have a QA/QC system in place.
Globally, macroinvertebrates are the most popular choice for use in bioassessment of stream health
(Gordon et al., 2004). Compared with other groups of organisms and parameters, they can be more
easily and reliably collected, handled and identified. In addition, there is often more ecological
information available for such taxonomic groups. Another factor which makes macroinvertebrates the
most broadly applicable group is that there are very few stressors to which macroinvertebrate
community structure is unlikely to respond (ANZECC and ARMCANZ, 2000). Macroinvertebrates are
not generally as sensitive to altered river flows as fish (Harris, 1995).
29
Fish assemblages
All jurisdictions except Northern Territory monitor fish as part of a river health program, but this is not to
say that fish monitoring does not occur in Northern Territory. The SRA fish monitoring protocol is the
most widely applied in Australia, with Victoria and NSW having decided to extend the methodology to
their coastal flowing rivers. The method of sampling design and site selection varies, as does frequency
of sampling (twice yearly to every five years). Reference is defined in a variety of ways, with the SRA
adopting a pre-European definition based on expert opinion.
Globally, fish are popular indicators because they are known to be sensitive to water quality, they are
known to have characteristic habitat preferences, are relatively easy to sample and identify in the field,
and they tend to integrate effects of lower trophic levels; thus, fish assemblage structure is reflective of
integrated environmental health (Barbour et al., 1999). As they have a relatively large range, fish are
best suited to assessing macrohabitat and regional differences. They are long-lived, so fish can
integrate the effects of long-term changes in stream health (Simon and Lyons, 1995). Fish populations
and communities can respond actively to changes in water quality, but are also strongly influenced by
changes in hydrology and physical habitat structure (ANZECC and ARMCANZ, 2000; Chessman and
Jones, 2001). Additionally, fish are highly visible and much valued by the wider community, so fish
monitoring usually has strong community approval and interest (Gordon et al., 2004).
Ecosystem processes
The SE Queensland EHMP is the only program in Australia to include an ecosystem process indicator.
The indicator combines three measures: algal growth (Chlorophyll a), change in which reflects the
change in shading by riparian vegetation and changes in ambient nutrient loads; carbon stable isotope
signature (δ13
C), change in which is associated with high rates of primary production, respiration and
methane production, and changes in stream flow; and benthic metabolism (respiration and gross
primary production), the rates of which increase with disturbance such as riparian vegetation removal
and agricultural runoff.
Riverine vegetation
The SRA is developing a method for assessment of riverine vegetation for the Murray-Darling Basin.
Western Australia has incomplete coverage, Northern Territory has a relatively small number of
sampled sites, while NSW and Victoria have good coverage and vegetation is included in the new
Tasmanian River Condition Index. The sampling is still mostly field-based, but remote sensing (with
associated ground truthing) may offer a viable alternative way of measuring aspects of vegetation in
certain situations.
The SRA methodology (under development) uses a hypothetical reference based on expected
conditions today without European influence. The Victorian method uses the similar notion of what the
vegetation community would look like under long-term undisturbed conditions. In Northern Territory the
reference is the previous measurement, while in NSW in the statewide census methodology the 2004/06
survey is used as the reference.
Riparian systems have an intimate connection with in-stream systems and appear to be sensitive
indicators of environmental change (Werren and Arthington, 2003). The riparian zone is the link
between terrestrial and aquatic systems (Auble et al., 1994), and Tabacchi et al. (1998) argued that this
zone is now well integrated into conceptual models of stream ecosystem functioning. A review of
existing methods for quantifying riparian vegetation as an indicator of stream health by Werren and
Arthington (2002) found that most methods measured structure and failed to consider activity
(metabolism or primary productivity), while few considered resilience [i.e. the three system attributes
that define health, according to Karr (1999)]. They developed a generalised rapid assessment protocol
for riparian vegetation that was claimed to address these shortcomings (Gordon et al., 2004).
30
Hydrology
The Flow Stress Ranking (FSR) procedure (SKM, 2005) is widely used in Australia. For example, the
Victorian ISC and the SRA use the FSR approach to calculating a hydrological index. Not all river health
programs in Australia include a hydrology index, with one example being the SE Queensland EHMP.
Site selection in the FSR has so far been largely controlled by the location of flow gauges, but other
sites can be modelled using a range of hydrological techniques. Reference condition in hydrology is not
pre-European, but unimpaired by water resources. So, the impacts of land use change are not
accounted for in the models.
Hydrological indices are easy to calculate but depend on the availability of an adequate hydrological
record - a serious limitation in many cases. Even where a discharge record is available, complex
modelling may be required to derive the unimpaired discharge record. While some recent progress has
been made on relating hydrological indices to ecological processes, this remains a major weakness of
using hydrological alteration indices as measures of stream health. Like the physico-chemical approach,
hydrological assessment and habitat assessment may identify the condition of the factors known to
threaten or enhance biota, but it says nothing about the actual condition of the biota (Gordon et al.,
2004).
Physical form
Physical form is not widely measured in a systematic way in Australia. Victoria and Tasmania have
considered physical form as part of their indices of stream health. The have been some problems in
achieving consistent and reliable application of the physical form sub-index of the Victorian ISC, which a
recent review of geomorphic methods did not resolve. The SRA is in the process of developing methods
for the Murray-Darling Basin. Queensland has used the State of the Rivers methodology for some time,
but there is not a lot of support to extend and maintain this program; some categorisation of reaches for
assessment has occurred in later State of the Rivers assessments based on classification by
Geomorphic Assessment of Rivers (GAR) methodology.
NSW has undertaken a considerable number of River Styles projects (a method of geomorphic stream
classification). River Styles includes post-classification stages, the first being assessment of river
condition to predict likely future river form, and the second being prioritorization of catchment
management issues, and identification of suitable river structures for Rivercare. With respect to stream
health monitoring, this work makes an indirect contribution, and thus is not listed here as a stream
health indicator.
One difficulty with physical form is that it can be challenging, even for an expert, to rapidly make
interpretations about process and rates of change on the basis of limited information or brief field
inspections.
Water quality
Only Victoria and Queensland have established state-wide water quality monitoring programs in place,
although NSW has a program in development and Northern Territory have a program for the Darwin
region. A range of parameters is measured, with temperature, turbidity and EC being the popular field
measurements (also pH, mainly because of ease of measurement, rather than being of central
importance to river health). Nutrients are also considered an important aspect of water quality, worthy of
monitoring. Reference can be known thresholds associated with low risks to achievement of healthy
ecosystems, or data from least disturbed systems.
Measurement of physico-chemical characteristics is a traditional, widely applied and robust approach to
assessing stream health. This has proved a valuable and necessary approach (especially for relatively
straightforward issues such as effluent compliance monitoring, drinking water standards and contact
recreation standards), but it does not explicitly measure the effects of concentrations of pollutants on
organisms. Physico-chemical profiling may identify situations where biotic communities are at risk, but
31
provides no information on the actual damage, if any, to the biota. Even where the tolerances of
organisms to individual pollutant concentrations are known, this information may have limited application
to the common situation of streams being affected by multiple pollutants, as well as habitat disturbance,
and hydrological alteration (Gordon et al., 2004).
Driver indicators including catchment disturbance
Driver indicators are not widely measured as an input to river health programs in Australia. Only the
Northern Territory and Queensland have made an effort to include this category of indicator.
Hunsaker and Levine (1995) raised the question of whether local or catchment-wide factors have more
of an impact on biotic integrity of streams. Lammert and Allen (1999) found that local land use and
habitat predicted biotic integrity while regional land use showed no relationship. In contrast, Roth et al.
(1996) in a study of the same catchment (but covering a larger area with greater contrast between sub-
catchments) found that regional land use factors were relevant to biotic integrity. The National Land and
Water Resources Audit (2002) assessment of river condition in Australia used an Aquatic Biota Index as
well as an Environment Index. The Environment Index combined the cumulative effects of catchment-
scale features (woody vegetation loss and development of infrastructure) and local features including
habitat (bed deposition, riparian vegetation cover and connectivity), hydrology, and nutrients and
suspended sediment loads.
The Filters approach
The Filters conceptual framework begins with a global or regional pool of species. Each species is
limited in its distribution by its tolerance to a range of environmental factors at a range of spatial scales.
For example, biogeographic barriers exclude those species that have been unable to disperse across
them, and high or low local temperatures exclude those species that cannot tolerate them (Walsh et al.,
2007).
If the potential range of each species within several environmental factors can be estimated, and the
conditions for each of those factors at a particular site can be quantified, then the pool of species that
could occur at that site can be estimated. A comparison of the species present at the site and those that
could potentially be at the site can form the basis of assessing the ecological condition of the site
(Walsh et al., 2007).
Filters is not really a river health protocol per se - it is a modelling approach to predict which families are
potentially present at a site in the absence of human impact (Walsh et al., 2007). While the Murray-
Darling Basin Filters model was initially developed for macroinvertebrates (Walsh, 2007), in theory it
could use any sampling protocol and any biota.
The attraction of Filters is that it is not necessary to rely solely on one sampling method to build the
model. Walsh (2007) used historical distributional data for one family of snail to develop a better model
of its likely pre-European distribution. This work demonstrated that the method is fairly robust to post-
European landscape changes, even in taxa that are known to have contracted their distributions. In
using the model, a single standard sampling protocol is necessary to standardize the likelihood of
collecting x families, so it will be easily applicable to current sampling protocols.
The outputs of Filters are similar to AusRivAS, i.e. O/E, but the method used to derive the Expected
suite of families is very different from (and a lot more transparent than) AusRivAS. SIGNAL O/E is
another possible output. This seemed to work a lot better than AusRivAS SIGNAL O/E, which has never
been seriously used because it is even less sensitive than AusRivAS O/E. Filters can also provide a list
of present-but-unexpected families, with reasons for their being unexpected, which is potentially a
powerful diagnostic. It is important to note that the Filters work of Walsh et al. (2007) utilized data
collected using AusRivAS sampling. Filters appears to overcome a difficulty in the AusRivAS protocol in
determining reference.
32
The development of Filters is still at a relatively preliminary stage. There needs to be substantial
assessment of its sensitivity (Walsh et al., 2007).
Monitoring environmental flows
A major program of environmental flows assessment has been established in Victoria, known as
VEFMAP (Victorian Environmental Flows Monitoring and Assessment Program (Cottingham et al.,
2005b). VEFMAP has been applied to a number of rivers (e.g. Chee et al., 2006a; 2006b).
The Integrated Monitoring of Environmental Flows (IMEF) program, established in New South Wales in
1997, is a systematic scientific program assessing the ecological benefits of environmental flow rules.
The program uses around 180 targeted sites on inland and coastal rivers to gather information and data.
A number of publication can be found at http://www.water.nsw.gov.au/Water-
Management/Monitoring/Regulated-rivers/default.aspx, including Chessman and Jones (2001) which
set out the program design, and Growns and Gherke (2005) which examined aspects of monitoring fish.
A major environmental flows monitoring program has been established for the Snowy River
(http://www.water.nsw.gov.au/Water-management/Monitoring/Snowy-River/Snowy-River/default.aspx).
A feature of this program was the extensive benchmarking work undertaken prior to implementation of
environmental flows (Rose and Bevitt, 2003; 2005). Gilligan and Williams (2008) reported on the
response of fish to flow releases.
Environmental monitoring at The Living Murray icon sites is undertaken to assess the success of
meeting environmental flow objectives for the River Murray. Monitoring aims to use adaptive
management techniques, where new data and information are considered as they become available,
and are incorporated into the planning process as relevant. The focus of The Living Murray monitoring is
on fish, birds and vegetation. The program includes both intervention monitoring to quantify
relationships between the cause (watering and other interventions) and the effects (ecological response)
at the icon site scale, and compliance monitoring to determine if works and watering regimes have been
undertaken as agreed
(http://www.mdba.gov.au/programs/tlm/programs_to_deliver/environmental_monitoring).
Products of river health monitoring
Australian jurisdictions generate a range of river health monitoring products for a range of audiences. In
general, the products tend to be mainly “Report Card” style; report annually to every 5 years; with data
collated and stored within the jurisdiction on various database systems; they aim to reach the public,
stakeholders, Government, consultants, scientific community, waterway managers, politicians and
Ministerial Council; are generally unrestricted in access; and are available on the internet.
Comparison of Three Australian Programs
South-East Queensland Ecosystem Health Monitoring Program
(SEQ EHMP) The Ecosystem Health Monitoring Program (EHMP) delivers a regional assessment of the ambient
ecosystem health for each of South East Queensland's (SEQ) 19 major catchments, 18 river estuaries,
and Moreton Bay. The monitoring program sits within a wider river health strategy known as the South
East Queensland Healthy Waterways Partnership. The objective of monitoring is to annually observe
and report the spatial patterns of river health and to report any apparent trend in the data through time.
These data are used within an adaptive management framework to maintain or improve river health.
The SEQ EHMP covers an area of 22,420 km2, which represents only 1.2% of the area of the state of
Queensland (Figure 5), but it contains two-thirds of the state’s population. The Department of
33
Environment and Resource Management (State of Queensland) runs a state-wide river and estuary
monitoring program, which until recently was known as the ambient monitoring program. It is in the
process of being replaced by the Stream and Estuarine Assessment Program (SEAP) (Marshall et al.
2006a). For more information on this state-wide program see the sub-section of this report headed
“Monitoring Application” and also the State of the Environment Report 2007 for Queensland
(http://www.derm.qld.gov.au/environmental_management/state_of_the_environment/state_of_the_envir
onment_queensland_2007/index.html).
Figure 5. South-east Queensland area covered by the SEQ EHMP, showing 15 major catchments.
The EHMP is managed by the South East Queensland Healthy Waterways Partnership on behalf of its
various partners and is implemented by a large team of experts from the Queensland Government,
universities and CSIRO. The EHMP website
(http://www.healthywaterways.org/EcosystemHealthMonitoringProgram/Home.aspx) provides an
overview of EHMP and details of methods, results and publications. While various publications from the
EHMP can be downloaded from the EHMP website, the summary provided here was sourced mainly
from a recent journal publication by Bunn et al. (2010).
The SEQ Healthy Waterways Partnership first articulated a vision for the future health of the region’s
waterways, then a broad range of values for the region’s waterways was identified through numerous
workshops with stakeholders from across the region. Measurable water quality and ecosystem health
objectives were then determined to protect these values. Research organisations in the region
collaborated to provide the rigorous science underpinnings for the monitoring programme. Finally,
management actions were identified to achieve these objectives, working directly with policy makers.
34
The SEQ Healthy Waterways Partnership adopted a staged approach in the development of the
strategy to achieve river health, beginning in the mid-1990s. The aim of the freshwater EHMP was to
“develop a cost-effective, coordinated ecosystem health monitoring programme for freshwaters of the
region that could be used to measure and report on current status and future changes in ecological
health and, where necessary, guide management actions.”
The program objectively evaluated a broad range of indicators against a known disturbance gradient to
identify those that best responded. An initial desktop study identified a suite of potential indicators of
ecosystem health, outlined initial monitoring protocols and developed a physical classification of stream
types in the study area. This initial phase concluded with a series of pilot studies for indicators that
required additional development before considering further. Next, a major field trial was undertaken to
test the short-listed indicators of ecosystem health across the known disturbance gradient. Results of
the major field trial were used to evaluate which indicators were most suitable for inclusion in the EHMP
for freshwaters.
Assessments for the Freshwater EHMP are based on 5 indicator groups: physical/chemical, nutrient
cycling, ecosystem processes, aquatic macroinvertebrates, and fish. The emphasis is on aquatic life
and water quality elements of the ecosystem (Figure 2). The program uses 18 indices that include
aspects of organisation (e.g. biodiversity, species composition, food web structure), vigour (e.g. rates of
production, nutrient cycling) and resilience (e.g. ability to recover from disturbance) (Figure 6).
Assessments are made in spring (pre-wet, October-November) and autumn (post-wet, April-May) each
year at 135 sites (mean density of sites is 1 site per 166 km2). The sampling sites are permanent, with
most locations selected randomly and also including some icon sites. The Estuarine/Marine EHMP
monitors 254 sites on a monthly basis. Technical data for all indicators are collected for each site and
summarised by catchment in a series of annual reports that are publicly available (e.g. Figure 6).
Each of the indicators is first standardised (0–1), where reference condition = 1 (for a particular stream
type) and values greater than or equal to the 90th percentile recorded or the theoretical minimum (e.g. 0
for invertebrate richness) = 0 (i.e. ‘worst case’). Indicators within each of the five indicator groups are
then averaged to produce a single value for each type, and presented as a pentagon (Figure 6).
A key element of the monitoring programme is the development and public presentation of annual
‘Report Cards’ on the health of waterways (Figure 7). The report cards are presented to politicians and
senior policy makers each year in a public (televised) ceremony. Data for each site within a catchment
for both seasons are averaged across all indicator groups to produce a single score for each reporting
region. These are converted to Report Card ‘scores’, where ‘A’ reflects a catchment in near reference
condition and ‘F’ is where the condition fails to meet the ecosystem health objectives that underpin
agreed values for the regions streams and rivers. Detailed indicator data available for each catchment
An important contributing factor to the success of the Healthy Waterways Partnership has been the
strong link between science and decision makers. Development of a relationship of mutual trust and
respect between the independent Scientific Expert Panel and decision makers has helped to achieve
targeted management actions.
Bunn et al. (2010) concluded that the key lessons from the EHMP that are probably transferable to other
situations were:
the importance of getting early agreement on a shared vision of the desired state of local
waterways into the future and adopting a cooperative and inclusive approach;
the involvement of committed individuals, including scientists, politicians, managers and
community members;
a need for defensible science and a commitment to a robust monitoring programme and
transparent reporting; and
effective communication
35
Figure 6. Example of a SEQ EHMP catchment report, showing summary results for the Bremer reporting area, including the distribution of values, both regional and sub-regional rankings, and change in relation to previous year. The top bar indicates spring 2006 and the bottom bar indicates autumn 2007.
Victorian Index of Stream Condition (ISC)
The state of Victoria monitors river health through the Index of Stream Condition (ISC). This program
is a part of the Victorian Government’s long-term plan for water, known as Our Water Our
Future (http://www.ourwater.vic.gov.au/programs/owof), specifically informing the Victorian
River Health Strategy (http://www.ourwater.vic.gov.au/environment/rivers/river-health-
strategy). The aim of the ISC is to provide a tool “for use by managers at state and regional
levels and can be used to report on stream condition, assist with priority setting, judge the
long-term effectiveness of rehabilitation programs and assist with adaptive management”
(Ladson et al., 1999).
36
Figure 7. SEQ EHMP report card for the entire SE Queensland region for 2007.
The ISC website (http://www.ourwater.vic.gov.au/monitoring/river-health/isc) claims that the
ISC is the first complete and comprehensive study of the environmental condition of rivers
anywhere in Australia and was also the first integrated measure of river condition in Australia.
The ISC was developed using information that could be easily understood, collected at the regional
scale and fed directly into regional planning exercises. In addition, the methodology had to be accurate,
easy to use, cost effective, based on good science and able to be undertaken by non-expert staff
trained in its use. The details of the ISC were first published by Ladson et al. (1999), and other
reports are available from the ISC website.
Five key components of river health are assessed every 5 years. These components, or sub-indices,
measure changes in hydrology, water quality, streamside zone (vegetation), physical form (bed and
bank condition and instream habitat) and aquatic life. Each of the 5 sub-indices comprises a number of
indicators, 22 in total, (Figure 8) that were developed and refined through a pilot study in four
catchments.
Figure 8. Indicators used to generate the ISC.
37
The state of Victoria covers an area of 227,416 km2. The ISC measures river health of 1,040 reaches,
representing 26,000 km of Victoria's major rivers and tributaries. The sampling represents a mean site
density of 1 site per 219 km2. Reaches are not randomly selected, but are chosen so that they are
relatively homogeneous in terms of the 5 components of stream condition (using ISC-independent data).
Streamside zone and physical form are measured in the field at 3 sites, selected by field operators to
take account of the reach-scale variability in apparent condition, and also taking accessibility into
account (note that ISC reach and site selection is not strictly random).
All ISC data and reports are available at the Victorian Water Resources Data Warehouse
(http://www.vicwaterdata.net/vicwaterdata/home.aspx). The data are reported at a number of spatial
scales, including at the state-level (Figure 9) the basin-scale and the reach-scale (Figure 10).
Figure 9. Victorian ISC state-wide results for 2004 survey, aggregated by river basin.
38
Figure 10. Victorian ISC Goulburn River Basin results for 2004 survey. Each point is a survey site, which is representative of a reach, with reaches being contiguous. In this way, the entire drainage network (at the mapped scale) is covered by the ISC. Inset shows report for Reach No. 7. Each sub-index is scored out of 10 to give a total score out of 50.
39
As well as including water quality and aquatic life indicators, the ISC includes two driver/stressor
indicators (Figure 2): hydrology and physical form. Hydrology was included on the basis that most of the
streams in Victoria have significantly altered hydrology, and it is open to management action through
implementation of environmental flows. The basis of the hydrology sub-index is comparison of the
current flow regime with the flow regime that existed under pre- water resources development
conditions. Streamflow data was required to determine current and unimpacted or natural flows for each
site. This data was derived from gauged records, streamflow models or rainfall runoff models developed
for previous studies. Where no gauged data or model data was available for a particular site, it was
transposed from another comparable site for which information was available. A minimum of 15 years of
monthly data was required. The indicators are calculated using the Flow Stress Ranking procedure
(DSE, 2005; SKM, 2005).
The physical form sub-index of the ISC has three indicators: impact of artificial barriers on fish migration,
large wood habitat availability, and bank stability. This sub-index was included because barriers, de-
snagging and bank erosion are recognised as widespread and serious stressors on stream health, and
because all three indicators can be practically addressed through management action. The ISC also
includes a streamside zone sub-index, the basis of which is a comparison of riparian vegetation
condition against expected reference condition. Riparian vegetation is both an ecological response
variable, and a driver variable, because of its impacts on temperature and bank integrity (Figure 2).
Data for the hydrology, aquatic life and water quality sub-indexes of the ISC are sourced from programs
that were already in existence at the time the ISC was developed (stream gauging network and REALM
streamflow modelling tool, the EPA’s standard Rapid Bioassessment protocol, and the Victorian Water
Quality Monitoring Network).
The ISC field surveys are either carried out by, or commissioned by, officers of the Catchment
Management Authorities, who are also responsible for undertaking river rehabilitation works, and also
administering the environmental flows assessment process. In this way, the ISC provides a very direct
link between monitoring and management actions.
Murray-Darling Basin Sustainable Rivers Audit (SRA) The Sustainable Rivers Audit (SRA) (http://www.mdba.gov.au/programs/sustainableriversaudit) is a
systematic assessment of the health of river ecosystems in the Murray-Darling Basin. It is overseen by a
panel of independent ecologists, the Independent Sustainable Rivers Audit Group (ISRAG). The data
collected by the SRA is a key input to the Basin Plan and other programs of the Murray–Darling Basin
Authority. The Basin Plan (http://www.mdba.gov.au/basin_plan) will be a strategic plan for the integrated
and sustainable management of water resources in the Murray–Darling Basin.
The ISRAG (Davies et al., 2008) provided assessments of ecosystem health for each of 23 major river
Valleys, using data gathered in 2004–07, on hydrology, fish and macroinvertebrates. This was a first
step toward analysis of trends, which will be a feature of later reports. The first in a triennial SRA series,
Davies et al. (2008) also described the framework of the SRA, from which this summary was drawn.
The Sustainable Rivers Audit aims to:
determine the ecological condition and health of river valleys in the Murray-Darling Basin ;
give us a better insight into the variability of river health indicators across the Basin and over
time;
eventually help us detect trends in river health over time; and
trigger changes to natural resource management by providing a more comprehensive picture
of river health than is currently available.
The indicators used in the SRA provide ‘windows’ on particular components of the river ecosystems,
and are grouped as Themes. Three indicator Themes (fish, macroinvertebrates and hydrology) were
40
chosen after assessing their cost effectiveness during a Pilot Audit conducted in four test catchments:
the Lachlan in NSW, the Condamine in Queensland , the Ovens in Victoria and Lower Murray in South
Australia. Indicators relating to floodplains, riparian (streambank) vegetation and the river's physical
form are in an advanced stage of development for inclusion in the next report of the Audit.
Fish communities and populations are sampled during normal flow conditions, across entire river valleys
in the one season, and once every three years at all 23 valleys in the Basin. Macroinvertebrate
populations are also be sampled during normal flow conditions, across entire river valleys in the one
season, but once every two years across the Basin. Hydrology information is collected every six years
and evaluated using long term river flow sequences, developed by the States. When there are major
changes to river flows through new structures being built or environmental flow provisions, the models
will require upgrading.
Regional and state/territory based river health monitoring programs usually focus on a particular
location, area or issue for a limited amount of time, and a range of methods are employed. The SRA
collects data in a standardised way for the entire Basin.
Within each of the 23 Valleys there are 1 – 4 Zones, defined in most cases by altitude – ‘lowland’ (0-
200 m AHD), ‘slopes’ (200-400 m AHD), ‘upland’ (400-700 m AHD) and ‘montane’ (>700 m AHD). Fish
and macroinvertebrate sampling sites in Valleys and Zones are selected using a constrained
randomization technique to minimise bias and distribute the sampling effort over space and time. In
future, as SRA cycles are repeated, one quarter of sites will remain fixed and the remainder will be re-
selected randomly. This will ensure a balance between logistical resources and statistically-reliable
measurements of differences between years, and in and between Valleys. In the SRA the site selection
is truly random, with field operators given coordinates of sites, selected regardless of accessibility.
Although this is preferable from a statistical perspective, it adds time and cost compared to non-random
sampling that takes convenience into account.
Davies et al. (2008) reported that 506 sites were sampled for the fish Theme and 773 sites for the
macroinvertebrate Theme. The Basin covers 1,061,469 km2, so these site numbers represent mean
sampling densities of 1 site per 2,100 km2 for fish and 1 per 1,370 km
2 for macroinvertebrates.
Hydrology data are derived from existing stream gauging and streamflow modelling sites, which are not
randomly located. The SRA employs indicators from the Flow Stress Ranking procedure (SKM, 2005).
Field data are processed in a series of steps leading to Metrics and Indices for each Theme in each
Zone and Valley. The Indices represent the Condition of the ecosystem component described by the
respective Theme, and the information from all Themes is combined by ISRAG to indicate Ecosystem
Health at the Valley scale. Indicators and indices are derived from metrics using ‘Expert Rules’, a
computational process based on ‘fuzzy logic’ (note: this is in contrast to the common approach of
summing indicators). This approach avoids the need for sharp, artificial boundaries between categories
of assessment.
Condition assessments for each Valley are related to a benchmark called Reference Condition. This
estimates the status of a component (for example, the fish community) as it would be had there been no
significant human intervention in the landscape. Reference Condition is a benchmark representing the
river ecosystem in good health, but is not a target for management. Condition is rated on a five-point
scale from Good through Moderate, Poor, Very Poor to Extremely Poor, depending on how different the
Theme components are from their respective benchmarks. The same scale is applied to Ecosystem
Health.
The SRA aggregated data into a compact summary of ecosystem health for the Valleys of the Basin
(Figure 11), and also presented results at the Valley and Valley Zone scales (Figure 12).
41
Figure 11. SRA compact summary – ecosystem health for all Valleys. Source: Davies et al. (2008).
42
Figure 12. Example of SRA Fish and Macroinvertebrate Theme reporting for the Border Rivers Valley. Source: Davies et al. (2008). Numbers on horizontal bars are medians, and vertical bars represent 95% confidence limits associated with the median.
Comparison
Aims
While the three monitoring programs summarised here differ in some respects, they share common
aims, the essential elements of which are to: (i) characterise current ecological health, (ii) report on
trends in ecological health through time, and (iii) use the results to inform river management.
Indicators
SEQ EHMP uses ecological response and water quality response variables (Figure 2), with a focus on
sampling in the field at times of low flow. The only physical variable is temperature. Direct measures of
stream disturbance (riparian canopy cover and channel integrity) were considered in a list of potential
indicators but were not included in the final list of indicators that responded well to the defined stream
disturbance gradient. The selected variables did respond well to the disturbance gradient, so they can
be said to be diagnostic of disturbance. The SEQ EHMP also has access to some driver/stressor data
through the State Landcover and Trees Study (http://www.derm.qld.gov.au/slats/meth.html) the
Queensland Landuse Mapping Program (http://www.derm.qld.gov.au/science/lump/index.html) and the
stream gauging network.
In contrast to the SEQ EHMP, the ISC was committed at the outset to including variables from indicator
groups that were directly associated with common management actions. In Victoria, most stream
rehabilitation work is concerned with channel stabilisation, riparian re-vegetation, and implementation of
Border Rivers
Fish Macroinvertebrates
43
environmental flows. This is a response to previous work which established that (i) streams were
significantly impacted by these issues, and (ii) these were major issues detrimentally impacting stream
health. In this way, the ISC can monitor progress in implementation of management actions, as well as
ecological responses to those actions.
The SRA also includes river health driver variables, with hydrology already included and physical form
and vegetation themes in development. The SRA does not include any water quality indicators. Davies
et al. (2008) did not indicate the rationale for including themes.
Water quality is a cornerstone of many river health programs worldwide, yet the SRA chose to exclude
it. One of the issues with monitoring water quality is that most parameters are highly variable through
time due to the high level of dependence on hydrology. Proper characterisation requires frequent
sampling, with most dedicated water quality programs sampling at 2-weekly or monthly intervals. This is
one of the main reasons why water quality monitoring is a relatively expensive exercise. In Victoria the
Victorian Water Quality Monitoring Network has been in place since the mid-1970s, covering 180 sites
(located at flow gauging stations) with monthly sampling of salinity, turbidity total nitrogen, total
phosphorus and pH (other parameters measured less frequently). In Queensland the Statewide Surface
Water Ambient Network covers 186 sites (located at flow gauging stations) with ad hoc sampling
(expected 4 times per year) of salinity, turbidity, dissolved oxygen, total nitrogen, total phosphorus and
pH. In New South Wales the Key Sites Surface Water Quality Program (being replaced by the Natural
Resources Monitoring, Evaluation and Reporting Strategy) monitored 99 sites for turbidity, temperature
and salinity at monthly intervals, but the frequency and coverage is less for other parameters. In South
Australia the EPA monitors 53 sites mostly in the more populated and developed areas (located at flow
gauging stations) at monthly or quarterly intervals, for nutrient, salinity, temperature, turbidity and pH.
When these data were audited in 2001 by the National Land and Water resources Audit
(http://www.anra.gov.au/topics/water/quality/), it was found that monitoring station density was too low to
characterise water quality within a number of smaller basins and more remote basins, and due to
limitations with the period of record and frequency of collection, in most cases trend analysis was not
possible on the full suite of variables monitored. Thus, the existing data are inadequate for a program
like the SRA. The SEQ EHMP measures water quality at only twice-yearly intervals, but attempts to
overcome the problem of variability with hydrology by only sampling at times of low flow. However, even
baseflow hydrology can be highly variable. In 2008-2009 the catchments of South East Queensland
received the highest rainfall in the last decade. The 2009 report card
(http://www.healthywaterways.org/EcosystemHealthMonitoringProgram/ProductsandPublications/Annua
lReportCards.aspx) found that while there were slight improvements in the biological health indicators
(aquatic macroinvertebrates and fish) associated with increased flows, these were offset by a general
decrease in the nutrient cycling indicator, and a decline in the physical/chemical indicator in many
catchments. The decrease in the nutrient cycling indicator reflected the overwhelming amount of diffuse
source pollution entering the streams. This illustrates the need for contextual information on the drivers
of river health, particularly discharge, when interpreting river health data.
Sampling
A major difference in the three Australian programs is in respect to sampling. The ISC and SEQ EHMP
use stratification and subjectivity in site selection, while the SRA uses random site selection within
Valley Zones. In the SRA, some sites require a good deal of effort and time by field crews to access, as
they are not necessarily close to roads and crossings. If a site is deemed inaccessible given a
reasonable amount of time and effort, operators choose the next site from a list of alternative, also
randomly selected, sites. In the SRA, the number of sites required was determined by power analysis to
be sufficient to detect change over a reasonable period of time, and to reliably characterise the health of
the Valley Zones.
The number of sites in the ISC was determined largely on the basis of the independent decision that a
reach would be 10 – 30 km long. The ISC originally used “representative” sampling within the reach
44
(operators trying to judge a site that appeared to represent the reach as a whole) but this was later
changed to ostensibly random site selection (access and apparent variability of the reach are also
considered).
For the SEQ EHMP, selection of the 53 sites for the major trial undertaken in 2000 was based around
an initial stratification into the four main stream types, and then aiming to cover the full range of the
disturbance gradient. For the full program, “a site was allocated to each 3rd
order stream and to the
catchments of all larger 2nd
order streams until adequate spatial coverage had been achieved” (Smith
and Storey, 2001, p. 11.16). This resulted in 120 sites “placed strategically across the study area”
(Smith and Storey, 2001, p. 11.16) (now 135 sites). Smith and Storey (2001) did not detail how the
actual site locations were determined, and the degree of autonomy of field crews in deciding the exact
spot to be sampled. In at least some instances sites were intentionally located in relation to certain
discharge points (such as sewerage treatment plants). The sampling strategy covers 60 – 70% of the
stream length in the SEQ region, under the presumption that a site represents a stream link. The
smaller streams are not represented in the sample. Reference sites were “minimally disturbed” which
effectively meant passing 9 out of 10 established criteria.
To investigate the trade-off between sampling density and uncertainty in meeting program objectives,
Ladson et al. (2006) undertook a detailed survey using the ISC method, sampling every second
kilometre of river on a 22 km long stretch of Ryans Creek and a 33 km long stretch of the Broken River,
in Victoria. In addition, experienced local Catchment Management Authority staff were asked to select
‘representative’ reaches. Sampling strategies were explored by random sub-sampling of the complete
data set. It was found that data from ‘representative’ sub-reaches could not be used to estimate the
population variance or realistic confidence intervals. The same conclusion was reached by other studies
from other parts of the world (reported in Ladson et al., 2006). For sampling densities less than 1 site
per 10 km, the precision of baseline assessments decreased rapidly as fewer sites were used. This
suggested that, for the purposes of a baseline assessment, 1 site per 10 km (with three transects per
site) would be a reasonable first estimate for the minimum sampling density for the ISC indicators.
Complete analysis to determine the best sampling scheme (number of sites per reach and transects per
site) would require consideration of the costs associated with visits to sites and transects, the total
budget for the sampling and the consequences of errors. Ladson et al. (2006) also found that the ability
to detect change accurately requires in the order of twice the sampling effort than assessing baseline
condition to achieve a similar level of precision.
Reporting frequency
There are significant differences in reporting frequency of the 3 Australian programs. The SEQ EHMP
reports annually, the ISC reports every 5 years, and the SRA reports a Basin-wide assessment every 3
years, and trends are reported every 6 years.
The more frequent the reporting the higher the awareness of the program and river health as an issue of
public concern, and the more rapidly management can respond to identified issues. However, there are
two main issues with reporting frequency that have to be balanced against the desire to report
frequently. The first issue is cost. Reporting data is a significant cost to the program, so the frequency of
reporting would be constrained by the available budget. The second issue has to do with the expected
rates of change in the indicators being monitored – there is little point in reporting data annually if the
measures are not expected to respond in a significant way to management actions or stressors over this
time frame. Also, trend is difficult to detect in a statistically significant way over short time periods.
Common factors
These 3 Australian programs have achieved recognition for successful achievement of their aims across
vastly different areas using different indicators, different sampling strategies, and different reporting
frequencies and reporting products. The factors that they do have in common, and which may be key
determinants of success, are:
45
Embedded within, and considered a critical component of, a wider river health strategy,
Well formulated and clearly articulated objectives,
A well funded phase of scientific program development and pilot testing in order to establish
indicators and protocols that would meet the agreed program objectives,
Technical manuals, operator training, and attention to quality control and assurance,
River condition reported relative to an established reference condition (although this can be
defined in different ways),
Strong levels of commitment by government and community,
Established formal links to river management,
Including indicators that directly measure the drivers and stressors of river health, or having
that informational available to the program to assist in explanation of water quality and
biological data,
Transparent, effective, and publicly accessible reporting, and
Ongoing critical review of the programs methods, and refinement and development as
necessary.
Lessons for China The implications of the comparison of 3 Australian programs for development of river health monitoring
programs in China are that:
Close attention needs to be paid to the factors that the Australian programs had in common,
and which may be key determinants of success,
The set of indicators should be chosen to suit the local conditions and the local objectives
rather than simply being copied from another program from another part of the world,
The program can focus on water quality and bioassessment, provided contextual information
on drivers and stressors is available, and provided the chosen indicators are diagnostic of
management issues – alternatively, the monitoring program can include driver/stressor
indicators that relate directly to intended management actions,
Full characterisation of spatial pattern and reliable trend detection in physico-chemical water
quality parameters requires an extensive network of frequently monitored sites, operational for
a long period of time, so the existing network in China should be utilised,
For field measured variables, careful attention should be paid to design of the sampling
strategy (sampling site location, number of sites, sampling frequency, and timing of sampling),
especially if one of the objectives is change detection, and
The reporting frequency needs to be appropriate to the expected rates of change in the chosen
indicators, and the benefits of frequent reporting need to be balanced against the cost of doing
so.
River Health Monitoring in P. R. of China
State of Environment reporting In China, SoE reporting for river health is based on National Surface Water Quality Standard (GB3838-
2002), which classifies chemical water quality into five classes for a range of indices (e.g. MEP, 2006).
Grade I is for water flowing through national nature reserves; Grade II is for the source of municipal
46
drinking water supply (first grade conservation area), conservation areas for rare aquatic species, and
areas for fish spawning; Grade III is for the source of municipal drinking water supply with treatment
required (second grade conservation area), conservation areas for common aquatic species, and areas
for swimming; Grade IV is for sources of industrial use and recreational use other than swimming (e.g.
boating and fishing); Grade V is for sources of industrial cooling water, irrigation water, and ordinary
landscape (Ma and Ortolano, 2000). A number of water quality indicators are used to define these
standards, with each parameter having a numerical limit for each class.
In 2006, among 745 water sections under national surface water quality monitoring program (593 river
sections and 152 lake or reservoir monitoring sites), 26 percent failed to meet Grade V national surface
water quality standard; 62 percent did not meet Grade III water quality standard; 90 percent of urban
river sections were subject to pollution at different degrees; 75 percent of lakes were subject to
eutrophication; 30 percent of drinking water source areas of key cities did not meet Grade III standard
(SCPRC, 2008). The main pollution indicators were permanganate index (the index of COD [chemical
oxygen demand], or measurement of all chemicals in the water that can be oxidized, which is an indirect
measure of industrial wastes), ammonia nitrogen (NH3 + NH4+ - N) (one of the three main forms of total
nitrogen, with the main source being fertiliser and untreated sewage), and petroleum (MEP, 2006).
Given this situation, it is not surprising that water quality has been the focus of river health monitoring in
China.
Over time, with the expansion of wastewater and sewerage treatment, and enforcement of strict
regulations on industrial pollution, water quality will become less of a limiting factor for ecological health
of rivers, and other limiting factors will likely become apparent. China's urban sewage treatment rate
increased from 34.2 percent in 2000 to 62.8 percent in 2007 (Research and Markets, 2008). According
to the 11th Five-Year Guideline, the average sewage treatment rate in cities in China will reach 70
percent by the end of 2010, and over 80 percent in provincial cities on average (SCPRC, 2008).The
target for total discharge of major industrial pollutants is a reduction of 10 percent (measured in terms of
COD load). All direct waste water outlets in Grade I protected areas for drinking water source will be
banned (SCPRC, 2008).
The SoE reporting of water quality data is currently the only method of national river health reporting.
The system of water quality monitoring in China is well developed with results widely reported using
simple statistics that relate directly to management activities and classes of river utilisation. The
variables do not necessarily relate closely to the health of the biota, but there is a broad recognition that
good water quality is necessary for proper ecological functioning.
Liao River Meng et al. (2009) described an integrated assessment of river health based on water quality, aquatic
life and physical habitat that they applied to the Liao River. In general, it was found that the water quality
of main stream and estuary, where industrial and agricultural activities are intense, was much worse
than that of the tributaries. Using Principal Components Analysis, water quality and physical habitat
quality indices were found to be important indicators of river health. Benthic index of biotic integrity (B-
IBI) showed the same spatial distribution as physical habitat measures (substrate, habitat complexity,
velocity-depth combination, bank stability, bank conservation, vegetation cover, vegetation diversity,
intensity of human activities, water cognition and riverside land use). The aquatic species surveyed
were attached algae and benthic invertebrates. It was concluded that control of heavy metal and nutrient
pollution would realise improvements in river health.
Yellow River Ni and Qian (2002) developed an integrated river health index for the Lower Yellow River [reported by
Foster et al. (2008) and Darton (2005)]. The index takes into account the length of river over which there
is no-flow, the amount of sediment, the severity of no-flow events which upset the river’s ecosystem,
47
and the availability of water for socio-economic development. It was found that the decline in river health
from the 1970s to 1997 was likely due to a combination of human and climatically induced trends.
Using the Yellow River as an example, Liu and Liu (2009) proposed that a healthy river has equilibrium
development between its natural and social functions; the indicators of a healthy river are favourable
riverbed, acceptable water quality, sustainable river ecosystem, and compatible flow in terms of the
river’s social and natural functions.
Liu et al. (2006) listed 8 indicators of river health for the lower Yellow River: minimum flow, maximum
flood discharging capacity, bank-full discharge, transverse slope of floodplain, water quality, area of
wetlands, aquatic ecosystem, and water supply capacity. The standards to be met were determined on
the basis of historical hydrological data and observed data from the period 1956–2004.
Pearl River Hydrology and water quality are routinely monitored in the Pearl River basin. Currently there is no
routine biological monitoring, although investigations have been undertaken at various times with algae,
fish and diatoms. A fish study was undertaken in the 1980, and again in 2006/07. A comparison of the
data showed a large decline in diversity.
Main Issues to be Considered in Design of a River
Health Monitoring Program
1. Objectives of the program (to be established by responsible agencies)
2. Sampling strategy (site location, number of sites, site selection strategy, frequency of sampling,
with an emphasis on scientifically sound methods)
3. Indicators selected for monitoring (relate to issues, assets, program objectives and likely
management activities, plus consider US EPA EMAP criteria). Either test a large number of
possible indicators in pilot studies, or chose a small number of indicators that are proven in the
literature.
4. Selection of suitable benchmark – must be consistent nationally
5. Quality Control/Quality Assurance methods
6. Production of manuals
7. Data management
8. Analytical methods (statistics, and development of composite index)
9. Sourcing contextual information to explain river health observations.
10. Reporting and communication methods (a policy is required for data and report access)
River Health Monitoring Framework
Recommendation: Framework 19. A generic river health monitoring framework for China is presented in Figure 13. This
framework is intended to guide the establishment of a structured river health monitoring
program within a river health strategy. Details of indicators, protocols and communication tools
will likely vary from area to area, depending on local conditions and priorities.
48
Figure 13. Generic High-level River Health Monitoring Framework.
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