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AN AQUAPONICS LIFE CYCLE ASSESSMENT: EVALUATING AN INOVATIVE METHOD
FOR GROWING LOCAL FISH AND LETTUCE
by
REBECCA ELIZABETH HOLLMANN
B.A., University of Denver, 2013
A thesis submitted to the
Faculty of the Graduate School of the
University of Colorado Denver in partial fulfillment
of the requirements for the degree of
Master of Science
Integrative Biology
2017
ii
© 2017
REBECCA HOLLMANN
ALL RIGHTS RESERVED
iii
This thesis for the Master of Science degree by
Rebecca Elizabeth Hollmann
Has been approved by the
Department of Integrative Biology
for
Greg Cronin, Co-Chair
John Brett, Co-Chair
Laurel Hartley
May 13th, 2017
iv
Hollmann, Rebecca Elizabeth (M.S., Integrative Biology)
An Aquaponics Life Cycle Assessment: Evaluating an Innovative Method for Growing LocalProduce and Protein
Thesis directed by Associate Professor Greg Cronin, and Associate Professor John Brett
ABSTRACT
In most states, only one to two percent of the food consumed comes from a source within
one hundred miles. The transition of food production to an industrialized global system has
increased the use of artificial fertilizers, pesticides, and fossil-fuels, which negatively affects
the environment, human health, and local economies. Actively promoting, optimizing, and
investing in local food systems can reduce society’s reliance on industrial food production.
Local food systems will become increasingly important due to the projected decreases in
food production from climate change, the increasing demand for food due to population
growth, and the nutrient pollution from current agriculture methods. Local food production
benefits include increased food security and sovereignty, improving local economies,
supplementary nutrition, preservation of genetic diversity, and fostering communities. The
current study is a life cycle assessment (LCA) of a local food production system known as
aquaponics. Aquaponics combines aquaculture and hydroponics in a recirculating engineered
ecosystem using minimal resources and generating negligible waste. This research evaluated
the global warming potential (GWP), energy use (EU), and water dependency (WD) of a
local aquaponics system. These values where then compared with literature studies of
traditional agriculture, hydroponics, and aquaculture. The LCA found that aquaponics
yielded 22.02 kg wet mass (WM)/m2 of lettuce production, or 560% higher than traditional
soil crop yield of 3.90 kg WM/m2 where hydroponics had the highest yield of 41.00 kg
(WM)/m2. Aquaponics had a lower WD than traditional agriculture, 0.06 m3/kg to 0.25 m3/kg
v
respectively, but a higher WD than hydroponics at 0.02 m3/kg. The EU for aquaponics was
10.58 mJ/kg, nine times lower than hydroponics at 90.00 mJ/kg of lettuce, but higher than
traditional agriculture records of 1.10 mJ/kg. Aquaponics had a GWP of 8.50 kg CO2
equivalency per kilogram of fish production, and 4.45 kg CO2 e/kg for lettuce production. All
other aquaculture systems had a higher EU and WD than aquaponics. Understanding the
costs and benefits to aquaponics may lead to better system management and long-term
decisions on the sustainability of aquaponics as an agricultural system.
The form and content of this abstract are approved. I recommend its publication.
Approved: Greg Cronin
Approved: John Brett
vi
AKNOWLEDGMENTS
This thesis would not have been possible without the collaboration and contributions
of Tawnya and JD Sawyer, owners and CEOs of Flourish Farms and Colorado Aquaponics.
Their meticulous attention to detail, record keeping, allowing me access to their database,
and answering my many questions is the foundation of this research. I also would like to
specifically thank Marielle D’Onofrio for answering many questions for me, finding specific
metrics and helping to gather data. My advisors at University of Colorado Denver, Dr. Greg
Cronin and Dr. John Brett, have been endlessly helpful in supporting my academic
development, mentoring me and guiding me through this thesis. I would also like to thank
my committee members, Dr. Alan Vajda and Dr. Laurel Hartley, for providing feedback and
support on this thesis. Thank you to Tamara Chernomordik for assistance with the GaBi V5.0
life cycle assessment software, and guidance on how to analyze the data on this software.
Also, an immense thank you to Stephen Fisher, PhD, who assisted me in the theoretical
frameset of my paper and understanding the Life Cycle Assessment method.
vii
TABLE OF CONTENTS
CHAPTERS
I. THE RELEVANCE AND BACKGROUND OF AQUAPONICS AS ANALTERNATIVE FOOD SYSTEM……………………………………………. 1
1.1 Introduction……………………………………………………………… 1
1.1.1 Inner workings of aquaponics……………………………………… 1
1.1.2 History of aquaponics……………………………………………… 3
1.1.3 Aquaponic system types…………………………………………… 5
1.1.4 Comparison System………………………………………………... 8
Hydroponics………………………………………………………….. 8
Aquaculture…………………………………………………………... 9
Conventional Agriculture……………………………………………. 9
1.1.5 Aquaponic production……………………………………………... 10
1.1.6 Aquaponic system potential………………………………………... 11
1.2 The importance of alternative food systems……………………………... 14
1.2.1 Climate change threatening food security…………………………. 14
1.2.2 The growing population: water and food demand…………………. 14
1.3 Relevant background…………………………………………………….. 16
1.3.1 Flourish Farms……………………………………………………... 16
1.3.2 Elyria Swansea neighborhood……………………………………... 19
1.4 Life cycle assessment practices………………………………………….. 23
1.4.1 Goal and scope description………………………………………… 25
1.4.2 Inventory analysis description……………………………………... 27
1.4.3 Impact assessment description……………………………………... 27
viii
1.4.4 Interpretation stage description…………………………………….. 28
II. AQUAPONICS LIFE CYCLE ASSESSMENT……………………………… 29
2.1 Introduction………………………………………………………………. 29
2.1.1 Research objectives………………………………………………... 30
2.1.2 Study site…………………………………………………………... 30
2.2 Methodology……………………………………………………………... 32
2.2.1 Goal and scope……………………………………………………... 31
2.2.2 Life cycle inventory……………………………………………….. 36
2.2.3 Life cycle impact assessment…………………………………….. 43
Allocation……………………………………………………………. 44
Total resource use………………………………………………….. 44
Conversion…………………………………………………………… 44
2.3 Results…………………………………………………………………… 45
2.4 Discussion……………………………………………………………….. 51
2.4.1 Impact assessment…………………………………………………. 51
2.5 Conclusion……………………………………………………………….. 58
REFERENCES…………………………………………………………………... 59
APPENDICES
A. Flourish Farm’s delivery locations…………………………………….. 66
B. Flourish Farm’s produce production……………………………………. 67
C. Flourish Farm’s integrated pest management use in 2014…………….. 69
ix
LIST OF TABLES
TABLES
1. Nutrient waste in a levee-style catfish pond 13
2. Pre-farm, on-farm and post-farm inclusions and exclusions in the LCA 34
3. Life cycle inventory of Flourish Farms 35
4. Electrical operational equipment at Flourish Farms 38
5. Necessary infrastructure in Flourish Farm’s aquaponic system 41
6. The total global warming potential (kg CO2 e), energy use (mJ) andwater dependency (m3) for Flourish Farm lettuce and tilapia and hybridstriped bass per kilogram in 2014.
47
7. Comparison of annual land use, water dependency, and energy use inaquaponics, hydroponics and traditional agriculture for lettuceproduction.
49
8. Comparison of global warming potential, energy use, and waterdependency of various aquaculture systems with values in terms of onekg produced.
50
x
LIST OF FIGURES
FIGURES
1. The recirculating principles of the aquaponics life cycle 3
2. The University of the Virgin Islands deep water culture (DWC)aquaponic facility.
5
3. Media based aquaponic system 6
4. Deep water culture root system 7
5. Nutrient film technology (NFT) aquaponic system 8
6. Layout of Flourish Farms 17
7. Flourish Farm’s DWC and main fish tank 18
8. Boundaries of Denver, Colorado zip code 80216 20
9. Major Toxic Releasing Inventory (TRI) facilities and super fund sites inor next to zip code 80216
21
10. Denver County food desert 22
11. Phases of a life cycle assessment 25
12. System boundary for the Flourish Farm LCA 33
13. Life cycle assessment process flow for fish 36
14. Life cycle assessment process flow for lettuce 37
15. Skretting’s Pond LE fish feed components 39
16. The GrowHaus delivery route 40
17. Global warming potential of fish production at Flourish Farms 46
18. Global warming potential of lettuce production at Flourish Farms 47
19. Distribution of global warming potential kg of CO2 e/ kg of productionwithin Flourish Farms.
48
xi
ABBREVIATIONS
CO2 Carbon Dioxide
DM Dry Mass
DWC Deep-Water Culture
EPA Environmental Protection Agency
EU Electricity Use
GHG Greenhouse Gas
GWP Global Warming Potential
HSB Hybrid-striped bass
ILCD International Reference Life Cycle Data Systems
IOS International Organization for Standardization
IPCC Intergovernmental Panel on Climate Change
IPM Integrated Pest Management
LCA Life Cycle Assessment
LCIA Life Cycle Inventory Analysis
NFT Nutrient Film Technology
TRI Toxic Releasing Inventory
USDA United States Department of Agriculture
WD Water Dependence
WM Wet Mass
1
CHAPTER I
THE RELEVANCE AND BACKGROUND OF AQUAPONICS
1.1 Introduction
1.1.1 Inner workings of aquaponics
This research assesses efficiency and output of a commercial aquaponics system known
as “Flourish Farms” in Denver, Colorado. The global food production system is projected to
decline in crop output due to climate change (Nelson, 2009), and population growth will
continue to exceed the carrying capacity of the planet (Barrett & Odum, 2000), which will
lead to a greater percentage of the world’s population receiving inadequate nutrition on a
daily basis. Current agricultural methods are a primary contributor to climate change and
environmental degradation. If current agriculture is further invested in and expanded in order
to meet the increasing demand, environmental collapse is expected (Edenhoger et al., 2014).
Alternative food production systems, such as organic, hydroponics, aquaculture, urban
gardening, and local food production offer a solution to steer away from the global food
system, and towards healthier and more sustainable crop output while revitalizing the
environment. Aquaponics is a promising system design to produce protein and vegetables
using minimal resources and waste production. This technology is in the early stages of
development worldwide with few commercial systems. Completing a Life Cycle Assessment
(LCA) on one of the well founded commercial systems in Denver will elucidate the resource
use, global warming potential and waste production of this aquaponics system.
Understanding the system value may lead to better system management, and long-term
decisions on the viability of aquaponics as a potential for year-round local food production in
temperate climates.
2
Aquaponic farming is a promising technology for local, sustainable food production.
Aquaponics combines aquaculture (e.g. aquatic animal farming) and hydroponics (e.g.
soilless systems for crop production) in a recirculating engineered ecosystem to
simultaneously produce vegetables and protein. Aquaponics systems have a high yield and
can annually produce 41.5 kg/m3 of tilapia and 59.6kg/m2 of tomatoes in a 1.2m wide, 0.33m
deep and 0.86m long tank with 4 plant plots (McMurtry et al., 1997). Aquaponic farms
utilize the effluent from aquatic animals rich in ammonium by circulating it to nitrifying
rhizobacteria to fertilize hydroponic vegetables. Nitrosomona species oxidize the toxic
ammonia (NH3) into nitrite, and then Nitrospira bacteria convert nitrite (NO2-) into nitrate
(NO3-), which is less harmful to the fish, but fertilizes the plants. The water, now cleansed of
ammonia, nitrates, and other nutrients after flowing through the bacteria matrix and root
system, circulates back to the aquaculture subsystem (McMurty et al., 1997) (Fig 1.).
3
Figure 1. The recirculating principles of the aquaponics life cycle. The fish excrete waste
products which are turned into nitrates from bacteria species such as Nistrospira sp. The root
system is then able to absorb these nutrients, and quickly grow into a harvestable product.
The fish are then supplied with clean water and are another harvestable product within time
(Engle, 2013).
1.1.2 History of Aquaponic
Although the term ‘aquaponics’ was coined in the 1970s, the science of aquaponics
developed long ago. One of the earliest was the Aztec agricultural islands known as
‘chinampas’ that would float on top of shallow lakes about 1,000 years ago (Crossley, 2004).
Aztecs would fertilize the islands with nutrient rich mud from nearby canals. Additionally, in
South China, Thailand and Indonesia grew fish in rice fields approximately 1,500 years ago
4
(Coche, 1967). This polyculture practice still exists today as hundreds of thousands of
hectares of rice fields are stocked with fish (Coche, 1967).
Development of contemporary aquaponic systems is practiced in warm and temperate
climates with many variations in system construction and cultivated species (Bainbridge,
2012). Modern aquaponics was first influenced by researchers studying recirculating
aquaculture systems who were looking for solutions to eliminate accumulations of nitrogen
(Love et al., 2014). One of the solutions researchers identified was to combine a soilless plant
system into the aquaculture system as a way of withdrawing the nitrogen compounds out of
the water. Present-day systems now rely on many hydroponic growing methods, such as use
of a greenhouse, and similar growing technologies.
One of the major revolutions to the aquaponics industry was the work of Dr. James
Rakocy, known colloquially as the Father of Aquaponics. He began further investigation of
aquaponics systems while working on his PhD at Auburn University, graduating with a
degree in aquaculture in 1980. He then developed an aquaponics facility at the University of
the Virgin Islands (UVI). The system started small, but continued to expand into a
commercial system which contains six hydroponic tanks with a growing area of 2,303 ft2 and
four fish rearing tanks containing 7798 liters of water each. In 1999 Dr. Rakocy started a
training program with students from all over the Unites States and territories. The system has
become an important tool in training students and educators about aquaponics all over the
world, and has proven to be successful in producing high quantities of fish and vegetables
(Rakocy, 2012). Dr. Rakocy and Dr. Lennard now teach a commercial aquaponics workshop
at UVI two times a year, which has been instrumental for the development of large scale
systems worldwide (Rakocy, 2012; Fig. 2).
5
Figure 2. The University of the Virgin Islands DWC aquaponic facility. UVI has one of the
best established and deep water culture aquaponic systems where they offer intensive training
course (Rakocy, 2012).
1.1.3 Aquaponic system types
There are three main types of aquaponic system constructions: media-based growing,
deep-water culture (DWC), and nutrient film technology (NFT). At minimum, a system will
have some form of a tank containing aquatic species, grow beds, and a pump. Most systems
contain a solids removal system; however, in media-based systems scuds and/or worms can
be added as an effective solids removal mechanism. Within the media-based growing there
are several different designs that can be put into place. There are basic flood and drain
systems, designs with sump tanks, constant height one pump systems, and even systems
using barrels (Bernstein, 2011; Lennard & Leonard, 2006). There are pros and cons to adding
sump tanks to a system. Sump tanks are second tanks kept without fish, where water will
continuously drain from the grow beds before recirculation. Designs without a sump are
typically much more simple and easy to construct, however the changing water levels can
add stress to the fish. Designs with a sump tank are more difficult to construct, but will keep
6
the water in the fish tank at a continuous level, which is ideal for the fish (Bernstein, 2011;
Fig. 3).
Figure 3. Media based aquaponic system with sump tank. In farms using media, the water
will flood and drain the system. Some advantages for the media based solution are growing
more root intensive crops, solid entrapment, and some systems use detrivores in the media as
well (Lovatelli, 2015).
The seeds in media based systems can be planted directly into the media, or transplanted
from nurseries. The media and root matrix is an efficient solids filter, and no other removal
system is needed. Media based systems also provide ideal growth environments for the
necessary bacteria. Another advantage to a media based system is this design allows the
greatest flexibility for what crops can be grown.
DWC systems use water filled beds with floating rafts which support the shoots above the
waterline, as the roots hang into the water. The roots hang into the water directly and the
bacteria can usually grow onto these extensive root systems without further assistance (Fig.
7
4). In some farms, the bacterial will cultivate within the solids removal and dentrification
tanks as well.
Figure 4. Deep water culture root system. In DWC systems, the roots hang loose into the
water culture on floating rafts (www.ColoradoAquaponics.com).
DWC aquaponic farms are more limited in what they can grow, and do require further
solids filtration. However, these systems are typically used in commercial aquaponics
facilities as they are relatively inexpensive to set up compared to other system types, and the
crops are considerably more easy to harvest than in a media based system (Bernstein, 2011).
The last type of system, NFT, uses condensed channels into which nursery plants are
transplanted, where a more concentrated stream of water flows through the root systems (Fig.
5). These systems look characteristically more like hydroponic systems. They offer many of
the same advantages and disadvantages of DWC systems, in that the crops are easy to
8
harvest, but the varieties that can be successfully grown are limited (Bernstein, 2011). This
system is primarily used for leafy greens and herbs, as other plants develop extensive root
systems that can easily block the channels (St. Charles, 2013).
Figure 5. Nutrient film technology aquaponic system. NFT systems are one of the most
common growing practices for hydroponic systems, and the technique has carried over into
aquaponics (Lovatelli, 2015).
1.1.4 Comparison Systems
Hydroponics. The word hydroponics is derived from the Greek roots of hydro and
ponos, meaning ‘working water’. The history of hydroponics dates back to 1929 with Dr.
William Gerich from the University of California (Love et al., 2014). In essence, hydroponic
farming is the science of growing plants without the use of soil, in a liquid culture
(Wignarjah, 1995). In hydroponic systems, nutrient solutions, mainly chemical salts, are
added to the culture that contains all the essential elements needed by the plant for its normal
growth and development. Like aquaponics, hydroponics can be developed with several
different designs, including NFT as one of the most popular techniques for producing leafy
greens. However, media based options are still used to support a larger variety of vegetables.
Many hydroponic systems are operated in controlled environment facilities in order to
9
increase the yield of the crops. Additionally, since the roots can easily obtain the necessary
nutrients in the synthetic liquid cultures, the yield is often much higher than conventional
agriculture (Love et al., 2014). Hydroponics also recirculates the water in order to more
sustainably nurture and support plant production.
Aquaculture. Aquaculture is the breeding, rearing and harvesting of plants and animals
within a water environment, which can range from ponds, rivers, lakes and the ocean.
Aquaculture has a long history of practice, dating back to 2,500 B.C. in China, with the
cultivation of common carp (Cyprinus carpio) (Rabanal, 1988). Near 500 B.C. Fan Lai wrote
a monograph names “The Classic of Fish Culture”, which is the first known description of
aquaculture practices. Aquaculture can also be known as aquafarming, which implies
intervention in the natural rearing process in order to enhance production. These practices
can range from stocking, feeding, and protection from predators (FAO, 2011). Today with
the decline of wild fish populations, aquaculture is a massive industry with over one half of
consumed fish products supplied by aquaculture facilities (Stanford University, 2009).
Conventional Agriculture. The modern industrial agricultural practice has historically
been defined as growing crops with soil, without cover, and treating the crops with irrigation,
nutrients, pesticides and herbicides (Barbosa et al., 2015). These traditional agricultural
techniques became popularized in the 20th century, which was known as the Green
Revolution (Hazell, 2009). With these technologies, conventional agriculture produces great
yields, but also has intensive resource requirements. Conventional agriculture is often
juxtaposed to organic farming, which does not permit the use of synthetic fertilizers,
pesticides, genetically modified organisms, or ionizing radiation or sewage sludge (USDA,
2016). These standards were developed in the late 19th century in central Europe and Asia.
10
1.1.4 Aquaponic Production
Aquaponics technologies have records of successfully raising many different types of fish
including: several varieties and hybrids of tilapia such as red tilapia (Oreochromis spp) and
Nile tilapia (Ocheochromis niloticus), and many other species such as yellow perch (Perca
flavescens), catfish (Ictalurus punctatus), striped bass (Morone saxatilis), rainbow trout
(Oncorhynchus mykiss), Arctic char (Salvelinus alpinus), barramundi (Lates calcarifer),
Murray cod (Maccullochella peelii peelii), common and koi carp (Cyprinus spp), goldfish
(Carassius auratus) and crustaceans such as red claw crayfish (Cherax quadricarinatus),
Louisiana crayfish (Procambarus clarkii), and giant freshwater prawn (Macrobrachium
rosenbergii) (Bainbridge, 2013).
There are over 60 species of plants successfully grown using aquaponics, and many more
in home hobby systems (Bainbridge, 2013). Leafy crops, such as kale, romaine and bib
lettuce, have typically been the most successful and can be grown in any of the above system
designs. In order for these plants to grow, they must absorb carbon and oxygen from the air,
and obtain water, macro and micro nutrients and light. In addition, plants require three
primary macronutrients (nitrogen, phosphorus, and potassium), three secondary
macronutrients (calcium, sulfur, and magnesium) and eight micronutrients (boron, chlorine,
manganese, iron, zinc, copper, molybdenum and nickel) to grow (Barker & Pilbeam, 2007).
In aquaponics, all of the macronutrients are obtained from the fish effluent that has broken
down and gone through nitrification. However, some studies have shown that the
concentrations of nutrients are not sustained over time if a non-supplemented fish diet is used
(Somerville et al., 2014; Al-Hafedh et al., 2008). Some studies have indicated that potassium,
iron, and calcium need to be incorporated within the system in order to have continued
11
healthy plant growth (Sommerville et al., 2014; McMurty, 1997). These nutrients are often
added as salts are used to balance the pH (e.g., potassium hydroxide and calcium hydroxide).
1.1.5 Aquaponic System Potential
As development of aquaponic systems spreads, many more individuals and companies
are realizing the benefits that aquaponics can offer, both environmentally and economically.
It is estimated that aquaponics uses about 10% of the water compared to soil crops
(Somerville et al., 2014; Lennard & Leonard, 2006). Water in soil crops is lost from
evaporation, transpiration, percolation in the subsoil, runoff and weed growth (Somerville et
al., 2014) Water use is at a minimum in aquaponic systems on the other hand, and may have
only a 1.4% daily water replacement (Al-Hafedh et al., 2008). The only water loss is through
crop growth, transpiration through leaves, and negligible evaporation from the soil-less
media. Because of this, the potential for aquaponics where water demand is high or
expensive should be further explored (Summerville et al., 2014).
In most aquaponic systems, artificial fertilizers are not used, which reduces
environmental pollutants and significantly reduces costs for the farm operations. Because the
crops are all grown soil free, there are no soil-borne diseases, no weeds and no tilling
required. Many aquaponic facilities are either constructed in greenhouse or in tropical
climates, and therefore can produce food year round and in places with poor soil quality.
One of the other major benefits aquaponics provides is low output of waste products,
whereas hydroponics, aquaculture, and conventional agriculture can all have significant
waste production. For either closed or open hydroponic systems the nutrient solutions
become out of balance and unusable, and the systems must be flushed about once every 30
days (Storey, 2016). The waste water is normally disposed of down into drains, and is filtered
by the city’s water treatment facilities (Quinta et al., 2013). In the long run, this solution may
12
not be efficient as facilities often require more money to deal with pollution loads that the
hydroponic facilities are producing, and in some cases may not even be able to extract all of
the excess nutrients. Dumping into water sources is highly regulated, with pressures from the
Environmental Protection Agency (EPA), United States Department of Agriculture (USDA),
Natural Resources Conservation Service, and State and Regional Water Quality Control
boards. Because of this, many growers find it hard to legally dispose of this water without
violating the Clean Water Act (Clean Water Act, 1972). The Clean Water Act maintains that
it is unlawful to discharge pollutants into water unless a permit is obtained. The main
components of hydroponic waste are phosphates and nitrates, which can lead to over
nourishment in bodies of water in a process called eutrophication. This will result in algal
blooms, which can deoxygenate the water and release toxins, often killing the flora and fauna
within. Wetland based waste water treatment options are being researched as a sustainable
solution to naturally filter the water (Quinta et al., 2013).
In order to maximize aquaculture production, efficient waste and solid collection methods
are important. Ammonia is the primary waste product excreted by fish across the gills as
ammonia gas (Rakocy, 1992). Un-ionized ammonia is extremely toxic to fish and can cause
tissue damage at concentrations as low as 0.06 ppm (Rakocy, 1992). 998 grams of ammonia
are produced from 45 kilograms of fish feed, and therefore the filters in aquaculture are a
crucial component of production (Rakocy, 1992). Fish effluent is characteristically high in
nitrogen, phosphorus and sulfate depending on the fish feed in use. In a levee – style catfish
ponds, nutrient input and output were measured (Tucker, 2009). The excreted nutrient
contents were very high in excess nutrients with nitrogen averaging 448 kg/ha and
phosphorus averaging 90 kg/ha (Table 1).
13
Table 1. Nutrient waste in a Levee-style catfish pond. The above concentrations were
measured, which demonstrates the high nutrient waste generated through aquacultural
production (Tucker, 2009).
Nitrogen Phosphorus
In feed (kg/ha) 560 112
Excreted (kg/ha) 448 90
Many aquaculture facilities dispose of their waste water directly into waters of the United
States, and therefore the EPA has set guidelines and regulations on what can be disposed of
(EPA, 2012). There are currently no numeric limits, but instead requiring best management
practices to control the discharge (EPA, 2016).
Traditional agriculture presents one of the largest water and nutrient concerns. World
agriculture requires approximately 70% of the fresh water withdrawn per year (Pimentel,
2004). For example, soybeans require 2,000 liters of water per kilogram of crop output, rice
requires 1,600 liters per kilogram, and wheat requires 900 liters of water per kilogram of
output (Pimentel, 2004). Research also projects that we are severely over fertilizing crops. A
study on corn fertilization showed a comparison between North China and United States
fertilization rates. China input 588 kilograms of nitrogen/ hectare a year, and 92 kilograms of
phosphorus per hectare a year with an output of 8,500 kilograms of corn/ hectare a year,
while the US input 93 kilograms of nitrogen/hectare and 14 kilograms of phosphorus/hectare
with an output of 8,200 kilograms of corn/ hectare (Vitousek, 2009). New solutions are
needed to combat both the nutrient discharge problems associated with hydroponics,
aquaculture, and conventional agriculture.
14
1.2 The Importance of Alternative Food Systems
1.2.1 Climate change threatening food security
The global food system contributes 21%-23% of total CO2 emissions, 55%-60% of total
CH4 emissions, and 65%-80% of total N2O emissions (Edenhoger et al., 2014). In 2014, the
Intergovernmental Panel on Climate Change (IPCC) reported with medium confidence that
the estimated temperature increases of 2°C or more will negatively impact production of
major crops by reducing production and increasing environmental threats to crops
(Edenhoger et al., 2014).
Current agricultural methods are extremely vulnerable to present, and future, effects of
climate change (Nelson, 2009). It is predicted that climate change will impact agriculture
biologically to the extent that the consequences will affect human health. Variation in
precipitation may result in short-term crop failures, and long-term production decline.
Decreased crops yields will in turn effect production, consumption and prices, which will
likely reduce per capita calorie consumption, and increase child malnutrition (Nelson, 2009).
It is projected that by 2050 child malnutrition will rise by 20% due to the decrease in calorie
production (Nelson 2009). Changes in death rate frequency will also influence the human
population size.
1.2.2 The growing population: water and food demand
One of the major problems facing future food producers is how to increase yields for the
growing population, while simultaneously using less land. The human population count on
November 2016 has reached 7.4 billion people, with an exponential projected growth for the
next 100 years (US Census, 2016). The future population growth is largely dependent on the
reproductive and death levels within the next 40 years (Cleland, 2013). In 2100, the
population estimates range with low projections of 6.2 billion to high projections of 15.6 +
15
billion; however, if fertility levels remain the same worldwide as they were in 2005-2010,
then the population would exceed 25 billion (United Nations, 2015). Despite these large
ranges of estimates, many experts have predicted that population increase will level off at
about 10 billion which has been predicted as the earth’s carrying capacity (Cleland, 2013;
Barret & Odum, 2000). Carrying capacity is defined as the population size the world can
support without damaging natural, cultural, and social environment and leaving future
carrying capacities intact (Aberneth, 2001; Barrett & Odum 2000). Thomas Malthus in 1798
discussed these principles in “An Essay on the Principles of Population” which describes
how human population growth is exponential, whereas natural resources grow arithmetically.
From this we can deduce that the population will at some point be unable to produce enough
food to support survival (Barrett & Odum, 2000). The long-term sustainability of the earth’s
human population depends on how countries handle human reproduction strategies, and the
ever pressing issue of how to produce larger quantities of food using fewer resources.
Even the population growth within the next 40 years will have major effects on the global
food supply chain as there will be approximately 2 billion more mouths to feed. The demand
for food during this period is predicted to increase by 50%, compared to the 30% population
growth (Barrett & Odum 2000). Misuse of soils, over-grazing, aquifer depletion, and loss of
biodiversity and ecosystems will be some of the inevitable consequences if we do not act
quickly. Aquaponics may be an effective solution to offset some of these concerns by
providing high vegetable and fish yield using no soil, minimal space and water, and increased
growth rates compared to soil crops (Al-Hafedh et al., 2008).
16
1.3 Relevant Background
1.3.1 Flourish Farms
This life cycle assessment was conducted at Colorado Aquaponic’s Flourish Farms, in
Denver, Colorado. This aquaponic farm is located within the GrowHaus, on York St. and 1-
70, in the Elyria-Swansea neighborhood. The GrowHaus is in a repurposed 1,858 square
meter greenhouse from the 1970’s, which functions as a non-profit indoor farm, marketplace
and educational center. They aim to create a community-driven, neighborhood-based food
system by serving as a hub for food distribution, production, education and job creation
(www.GrowHaus.com).
Food is produced year-round at the GrowHaus with three separate sustainable and
innovative indoor growing farms: hydroponics, permaculture and aquaponics. The scope of
this study will concentrate on the aquaponic farm ‘Flourish Farms’ which occupies 297
square meters within the GrowHaus (Fig. 6).
17
Figure 6. Schematic of Colorado Aquaponic’s Flourish Farms. The image depicts the
integration of deep-water culture (DWC), nutrient-film technology (NFT), and media beds
for growing produce (Images used with permission from JD Sawyer).
Flourish Farms contains all three types of aquaponic systems (DWC, NFT and media
beds) as the owners showcase the various construction designs for aquaponics systems. The
farm used a tilapia and koi carp combination for many years, due to these fish’s resilience
and fast growth rates even under high stocking densities (Fig. 7).
18
A.
B.
Figure 7. Flourish Farms deep water culture and main fish tank. (A) DWC raft system. The
image shows the four raft beds that carry the leafy greens vegetable output. (B) Fish
production. This tank picture demonstrates the tilapia and koi fish that supply the nutrients for
the system (www.ColoradoAquaponics.com).
However, throughout 2014 and 2015 they switched to striped bass, recognizing a greater
value and preference for this fish in their customer core (Tawyna Sawyer personal
communication, 2015). They have also successfully raised catfish and bluegill. Since
Flourish Farms moved into the GrowHaus in 2012 they have grown hundreds of different
19
varieties of vegetables and have sold over 13,608 kilograms of food within an eight kilometer
radius. They also continue to donate 10% of their crops to the GrowHaus, contributing to the
local community (Tawyna Sawyer, Personal communication 2015).
Flourish Farms was founded in 2009 by owners and CEOs Tawnya and JD Sawyer. The
farm serves not only as a commercial production center, but also as a model system that has
been mimicked in schools, community buildings, correctional facilities, and homes. As part
of Colorado Aquaponics’ mission, they provide aquaponic training, curriculum, consultation
and support programs that can be delivered to individuals, schools, institutions and
communities looking to take charge of their own sustainable farming and food security
(www.ColoradoAquaponics.org).
1.3.2 Elyria Swansea neighborhood
One of the GrowHaus’s main priorities is to provide fresh produce and protein to the
Elyria Swansea neighborhood and zip code 80216 in which they are located (Fig. 8).
20
Figure 8. Boundaries of Denver, Colorado zip code 80216. This area includes the Elyria
Swansea neighborhood as well as sections of Northfield, and the River North Art District.
The white star indicates the approximate location of the GrowHaus within this neighborhood
(Google Map Data).
The Elyeria Swansea neighborhood was established in 1880 as a working class
community and has long been surrounded with industrial buildings and transportation
infrastructure. This neighborhood is well known for being the most polluted zip code in the
state (Fig. 9).
21
Figure 9. Major Toxic Releasing Inventory (TRI) facilities and super fund sites in or next to
zip code 80216. See Appendix A for full listing of Sites and Contaminants. There are 8
Superfund sites in this area, with the most toxic release in this zip code has an EPA Hazard
ranking of 70.71 (max 100), and the top ten TRI facilities release 132,342 kilograms of toxic
chemical per year (last recorded in 2013). In the above map these are labeled 1 – 10, and the
other blue squares indicated other reporting facilities in this area (NIH TOXMAP, 2013).
In this neighborhood there are approximately 10,700 residents, out of which 36% live in
poverty with the lowest average household income in the state and 34% are under the age of
18 (Cran Communications Inc., 2015). The residents here have long lacked access to
healthy, affordable food, and the area is classified as a food desert in accordance with the
USDA definition (Fig. 10).
22
Figure 10. Denver County food deserts. The above shaded areas are the 19 census tract areas
that are classified as a food desert based on the USDA’s definition (USDA Data, Google
Earth Image).
‘Food desert’ is a term that has been used in public health and academia in order to
describe the food insecurity associated with residents in a geographical area having little
access to healthy food. The USDA quantifies this as a low-income census tract area where a
substantial number or percentile of residents have low access to a supermarket or a grocery
store. Low income is described as fitting the eligibility requirements of the Treasury
Departments New Market Tax Credit program. An area described as low access is further
than one mile from a supermarket or grocery store in an urban area, or ten miles in a rural
area (Dutko et al., 2012).
In order to combat this food injustice, the GrowHaus offers their weekly, year-round food
box at a discounted price for these residents. The food boxes include local fresh farm eggs,
and fruit and vegetables from local and often organic farmers. They also include organic
leafy greens from their own aquaponics and hydroponic systems. Each weakly box also
23
includes a complex carbohydrate of either freshly baked bread or tortillas
(www.Growhaus.com).
In addition to selling produce and fresh fish to the residents in the nearby neighborhood,
Flourish Farms sells the majority of its produce to top restaurants in Downtown Denver, all
within five miles of the farm (Appendix A). These restaurants include The Populist, The
Plimoth, Vesta Dipping Grill, Jax Fish House, Thump Café, SAME Café, Mondo Market at
the Source and Marzyck’s Fine Foods (www.ColoradoAquaponics.org).
1.4 Life Cycle Assessment Practices
This research investigated the environmental sustainability and cost effectiveness of an
alternative for producing local food. Although there are many aquaponic systems in
production, especially in the last few years, little research has been conducted on the cost
effectiveness or ecological efficiency of aquaponics. In order for aquaponics to be considered
as an alternative food system this analysis is critical and necessary in order to justify large
investment and production.
One of the most widely used techniques to determine the environmental impacts of a
system is a Life Cycle Assessment (LCA). LCA assessment began in the 1960’s when
scientists concerned with fossil fuel depletion and natural resource loss were seeking a
method to evaluate resource consumption (Svoboda, 1995). An LCA is defined as a
systematic evaluation of the environmental aspects of a products life cycle stages. These
stages can include a cradle to grave approach, which implies considering a products ‘life’
from raw material acquisition, to manufacturing, product assembly, maintenance, product
disassembly and disposal (Akundi, 2013). Rebecca Bainbridge completed the first LCA of a
temperate aquaponic system in 2012, looking at environmental implications such as the
global warming potential, non-renewable energy use, eutrophication potential, acidification
24
potential, and water dependency. This report is an important first step, but many questions
and variables remain to be tested which this study hopes to achieve.
An LCA first compiles an inventory of relevant energy and material input, as well as
releases. These components are then evaluated and for the potential impacts of the inputs and
releases (International Organization for Standardization, 1997). Once this is completed, an
improvement analysis can be conducted in order to determine opportunities to reduce energy,
material inputs, or environmental impacts at each stage of the life cycle. LCAs have recently
taken on importance in environmental policy making, as global stakeholders are beginning to
feel pressure to reduce their environmental impact (Goedkoop et al., 2013). From the
international concern, the International Organization for Standardization (ISO) created
principles and framework for voluntary, consensus-based, LCA standardizations for
countries to follow so that studies across that world can be compared to combat global
problems. LCAs provide the quantitative data for discussion and initiative to take place in
order to reduce environmental impact.
The methods for conducting an ISO 14040 LCA consist of four phases (ISO, 2006; Fig.
11):
1. The goal and scope will define the purpose and system
2. The inventory analysis will list the materials and energetic inputs
3. The impact assessment will evaluate the environmental effects
4. The interpretation stage will conclude with recommendations for improvements.
25
Figure 11. Phases of a Life Cycle Assessment. (ISO 14040, 1997).
1.4.1 Goal and scope description
The first step of an LCA is to define the goal and scope of the system. This step includes
many variables and questions that must be determined before the start of the project. There
must be a clear reason for executing the LCA, a precise definition of the product and its’
functional unit, the system boundaries, data requirements, data assumptions, intended
audience, how the results will be communicated, and how a peer review will be made
(Goedkoop et al., 2013). There are many different approaches to completing an LCA
depending on goal, resources, and data available. There are three different orders of LCA
analysis (Goedkoop et al 2013):
I. Only the production of materials and transport and included
II. All processes during the life cycle are included but the capital is excluded
26
III. All processes including the capital goods are included. Usually the capital goods
are modeled in a first order mode, so only the production of materials needed to
produce the capital goods are included.
Many LCAs do not include capital goods, which can reduce the data requirements for the
analysis. In some systems capital contributes up to 30% of the environmental impact, so it
can be beneficial to include the data in the boundaries (Goedkoop et al., 2013). LCAs can
also differentiate on whether it includes the entire scope of environmental impact or focus in
on single issues, such as carbon footprinting or water footprinting. In general the impact
categories include (Goedkoop et al., 2013):
• Non-renewable resources (with and without energy content)
• Renewable resources (with and without energy content)
• Global warming (CO2 equivalents)
• Acidification (kmol H+ equivalents)
• Ozone layer depletion (kg CFC11 equivalents)
• Photochemical oxidant formation (kg ethane-equivalents)
• Eutrophication (kmol N+ equivalents)
The boundaries of an LCA also include establishing the ‘scope’ of the environmental
issues that will be reported, such as greenhouse gases. GHGs are classified into three
different scopes based on the GHG Protocol Corporate Standard. Scope 1 emissions are
directly from sources that are owned or controlled by the system, such as vehicle emissions
or emissions from chemical production. Scope 2 emissions are indirect emissions from
sources that are purchased by the system, such as the emissions generated from purchasing
energy, where the emissions occur at the facility where the energy is generated. Scope 3
emissions are additionally indirect emissions that are not reported in Scope 2, that are in the
27
value chain of the reporting company, both upstream and downstream. Scope 3 emissions
include extraction and production of purchased materials. LCA software has Scope 3
emissions databases for all processes that are reported.
1.4.2 Inventory analysis description
The inventory analysis encompasses the task of collecting the necessary data in order to
perform the LCA. There are two types of data, foreground data which refers to data that
describe a particular product, and background data which are data for the production of
generic materials, energy, transport, and waste management. Foreground data must be
collected from the system itself, whereas LCA software, such as GaBi V5.0, contains the
necessary background data, such as the scope 2 and 3 emissions of certain processes. LCA
software helps to manage data and model the LCA within the ISO standards. GaBi V5.0 has
several options for creating process maps and flows and has several analyzing and
interpreting selections (www.GaBisoftware.com). Questionnaires are often helpful during
foreground data collection in order to gather all required information. In order to gain the
background data, the GaBi V5.0 software has a database covering 10,000 processes in the
EcoInvent and U.S. LCI databases (Goedkoop et al., 2013).
1.4.3 Impact assessment description
Impact assessment of an LCA is an analysis to determine environmental impacts
throughout a product’s lifetime. This phase is aimed at understanding and evaluating the
significance of impacts of the production system (Goedkoop et al., 2013). In order to do this
in compliance with the ISO, a classification and characterization need to take place. GaBi
V5.0 software has many available impact assessment methodologies built in to its program
that can be used depending on the goal and scope of the system. The results will typically
display which inventory items are contributing to the environmental factors, and to what
28
degree. The impact assessment analysis can have many stages, including; allocation, total
resource use calculations, library determination, and conversions. If necessary, allocations
will be determined by the end user. Library determination depends on what software
databases are available, and which elements the end user is trying to analyze. Conversions
into the same function output unit are typically done within the software.
1.4.4 Interpretation stage description
The interpretation stage is described by ISO 14044 as the number of checks to test
whether conclusions are adequately supported by the data (2006). In GaBi V5.0 software this
exists as a checklist that will review relevant issues mentioned in the ISO standard. These
exist mainly as uncertainty in the analysis, such as variation in the data, correctness of the
model, and incompleteness of the model. Once these aspects are evaluated, the model can be
looked at to see if any hot spots exist, or areas of consumption that are causing large
environmental impact. These hot spots can be recommended for system improvement design
changes in order to reduce environmental impact. This stage will also be used to compare the
results of an LCA to another applicable system or product in order to discern which system
can have more viability and less environmental impacts long-term.
29
CHAPTER II
AQUAPONICS LIFE CYCLE ASSESSMENT
2.1 Introduction
This research assessed the operational production and sustainability potential of Colorado
Aquaponic’s commercial system ‘Flourish Farms’ located in Denver, Colorado in the United
States. Aquaponic farming is a promising technology for local, sustainable food production.
Aquaponics combines aquaculture and hydroponics in a recirculating engineered ecosystem
that utilizes the effluent from aquatic animals rich in ammonium by circulating it to nitrifying
rhizobacteria to fertilize hydroponic vegetables. Nitrosomona species oxidize the toxic
ammonia (NH3) into nitrite, and then Nitrospira bacteria oxidize nitrite (NO2-) into nitrate
(NO3-), which is less harmful to the fish, and a nutrient for the plants. The water, now
stripped of most ammonia and nitrates after flowing through the bacteria matrix and root
system, circulates back to the aquaculture subsystem (McMurty et al., 1997) This system
design can annually produce up to 41.5 kg/m3 of tilapia and 59.6kg/m2 of tomatoes in a 1.2m
wide, 0.33m deep and 0.86m long tank with 4 plant plots (McMurtry et al., 1997).
The global food production system is projected to decline in crop output due to climate
change (Nelson, 2009), and population growth will continue to exceed the carrying capacity
of the planet (Barrett & Odum, 2000), which will lead to a greater percentage of the world’s
population receiving inadequate nutrition on a daily basis. Current agricultural methods are
some of the primary contributors to climate change and environmental degradation, and if
they are further expanded to meet the increasing demand, environmental collapse is expected
(Edenhoger et al., 2014).
In place of a global food production systems, hydroponics, aquaculture, urban gardening,
and local food production offer an alternatives, and aim for a healthier and more sustainable
30
crop output while revitalizing the environment. Aquaponic technology is a system designed
to produce protein and vegetables using minimal resources and waste production.
Aquaponics also offers a solution to the difficulties of acquiring protein locally and
affordably. One four ounce serving of tilapia incorporates 50% of the daily protein
requirements for men, and 60% for women (USDA SR-21, 2014). This technology is still
used as a niche farming method with only 257 systems out of the 809 United States systems
surveyed in 2014 operating on the commercial scale, with all others classified as backyard or
hobby systems (Love et al., 2014). However, aquaponics is a rapidly growing field as over
600 systems have been built in the United States from 2010 to 2013 (Love et al., 2014).
Completing a Life Cycle Assessment on one of the well-founded commercial systems in
Denver will elucidate the WD, EU and GWP of this aquaponics system.
2.1.1 Research Objective
In order to further examine and assess aquaponics as a method to grow high quality food,
we performed an LCA on the commercial aquaponics system in Denver, Colorado, which
compared the GWP, WD and EU to literature recordings of resource use in conventional
agriculture, aquaculture, and hydroponics. This analysis will enable the end users to take into
account where inefficiencies in the aquaponic process may exist, and how to improve
operations for a more sustainable system. The literature comparisons will help those
interested in the aquaponic field to understand the benefits and resource requirements for the
system, in contrast to other available options.
2.1.2 Study Site
The LCA took place at Flourish Farms, run by Colorado Aquaponics, within the
GrowHaus. The GrowHaus is in a historic 1,858 square meter greenhouse which functions as
a non-profit indoor farm, marketplace and educational center. They aim to create a
31
community-driven, neighborhood-based food system by serving as a hub for food
distribution, production, education, and job creation (www.GrowHaus.com). Food is
produced year-round at the GrowHaus with three separate sustainable and innovative
growing farms: hydroponics, permaculture and aquaponics. The scope of this study will
concentrate on the aquaponic farm ‘Flourish Farms’ which occupies 297 square-meters
within the GrowHaus.
Flourish Farms was founded in 2009 by owners and CEOs Tawnya and JD Sawyer. The
farm serves as a commercial production center and as a model system that has been
mimicked in schools, community buildings, correctional facilities, and homes. As part of
Colorado Aquaponics’ mission, they provide aquaponic training, curriculum, consultation
and support programs that can be delivered to individuals, schools, institutions and
communities looking to take charge of their own sustainable farming and food security
(www.ColoradoAquaponics.org).
The farm contains three types of aquaponic systems, deep water culture (DWC), nutrient
film technique (NFT) and media beds, as the owners showcase the various construction
designs for aquaponics systems. Flourish Farms used a tilapia and koi carp combination for
many years, due to their resilience and rapid growth under high stocking densities. However,
they gradually switched to hybrid striped bass (HSB) in 2014 and 2015, recognizing a greater
value and preference for this fish by their customers (Tawnya Sawyer, personal
communication 2015). They have also successfully raised catfish and bluegill. Since Flourish
Farms moved into the GrowHaus in 2012, they have grown hundreds of different varieties of
vegetables and have sold over 13,607 kg of food within an eight kilometer radius.
32
2.2 Methodology
The LCA follows the ISO 14040/14044 guidelines (ISO, 2006) and is separated into four
sections: (1) goal and scope definitions; (2) inventory analysis; (3) impact assessment and (4)
interpretation (as presented in the ‘Results’ and ‘Discussion’ section of this paper).
2.2.1 Goal and scope
This LCA is considered a streamlined LCA, as several processes in a cradle-to-grave
analysis were omitted for this study. However, streamlining the LCA process is an essential
element in the goal and scope definition, as few LCAs are full-scale due to time and cost
constraints, according to Todd & Curran (1999). Streamlining allows the study designers to
select an approach and level of rigor that is appropriate for the intended end users and
application of the study.
In this research, the goal of the study was to determine the life cycle GWP, WD and EU
from a commercial aquaponic system in Denver, CO. A second goal was to compare the
results from this study to other literature LCA values from hydroponics, aquaculture and
conventional agriculture to evaluate if any of these systems offer environmental efficiencies
for agricultural production. These goals were achieved by forming a functional unit,
constructing system boundaries, and gathering the required data.
In order to accommodate for the production of two products in this agricultural system,
two separate LCA analyses were completed with allocations for resource use. The functional
unit for the lettuce production is 1 kg WM lettuce. Dry mass (DM), although a more accurate
measure as it excludes fluctuations in water concentrations, was not used for this study as
Flourish Farm measures every full lettuce head weight right after harvest and before
delivering to the costumer. Flourish Farms produced 60 different types of leafy greens during
the 2014 year (Appendix B), which for this study will all be referred to as “lettuce”. Each
33
species of lettuce was weighed at harvest and recorded and the average sell weight was
calculated. The second LCA analysis focuses on the fish production of the aquaponic farm,
with a functional unit of 1 kg of fish. Flourish Farm produced two different species of fish
during 2014, tilapia and HSB which both together will be referred to as ‘fish’. For this
analysis, a fish mass estimation had to be used, as the farm currently sells their fish whole
and only occasionally weighs them. Fish mass was estimated from personal communication
with owner Tawnya Sawyer, as well as notes in the sales section of the data report indicating
approximate fish size and occasional weights. The weights were categorized into small
(~28gm), medium (~170gm) or large (~396gm) for each fish sold.
The system boundary is a single issue LCA approach, with an Order I analysis focusing
on the production cycle and transportation of the farm in order to ascertain the global
warming potential, energy and water use within the farm for the entire 2014 year. The scope
includes the energy carriers, natural gas consumption, water use, integrated pest
management, delivery transportation, and the input of fish feed into the system (Goedkoop et
al., 2013; Fig. 12).
34
Figure 12. System Boundary Colorado Aquaponic’s Flourish Farms LCA. The above figure
demonstrates a flow diagram of the boundaries of the LCA for this study. This study included
the fish feed production, water acquisition, water use, pump use, lighting use, integrated pest
management, heating and cooling mechanisms and the transport to the customers. Excluded
from the study were the nutrient additions and the background analysis of the capital units
used in production and transportation.
In order to clarify the system boundaries, the components were divided into ‘pre-farm’,
‘on-farm’ and ‘post-farm’, which will help elucidate the areas outside of the system boundary
(Table 2).
35
Table 2. Pre-farm, on-farm and post-farm inclusions and exclusions in this study.
Pre-Farm On-Farm Post-Farm
Inside
Study
Boundary
• Fish feed production
• Pest management
production
• Heating
• Cooling
• Lighting
• Pumps
• Water
additions
• Transport to
customer
Outside
Study
Boundary
• Infrastructure
production
• Capital production
• Nutrient production
• Materials transport to
farm
• Nutrient
additions
• Packaging
• Storage
• Consumption
stage
• Waste
generation
• Avoided
products
The WD and GWP were both calculated using GaBi Product Sustainability Software
version 5.0. GaBi V5.0 which generates the LCA of a product according to the ISO
14040/14044 regulations, and uses the PAS 2050 and GHG Protocol Product and Scope 3
Standard to specifically generate the carbon footprint. For this study, the GaBi V5.0
International Reference Life Cycle Data System (ILCD) was used, using the U.S. Life Cycle
Inventory and EcoInvent databases.
Outside of the scope of the study were the capital resources of the farm, which included
the ‘cradle’ production costs of greenhouse structure, tanks, piping, motors, heaters, fans,
lights and additional building materials. Additionally, the functionality of this study for
Colorado Aquaponics did not need the extensive rigor to include the capital, but rather
focusing on the production hot spots accomplished the goal. In future studies of the farm,
36
these elements could be inventoried and included. Also, many of the nutrient additions to the
farm in 2014 were not categorized for which chemicals were included. For instance, a
“homebrew” nutrient mixture compromised 90% of the total nutrient additions for 2014, but
this mixture was constantly changed and no notes were provided as to what was included in
each supplement. Because of these inconsistencies, the nutrient additions were excluded.
However, the main nutrient supply to the system is the fish effluent, which has zero
environmental impact, and allows comparison of this study to others that do include nutrient
additions. Other limitations were the specific integrated pest management chemicals that
were used were not available in either database. However, a general pesticide application was
found which was used for this study. The water use in this study was pulled from the Denver
Water meter bills, and included all of the use on the farm – not just the usage for production.
In future studies, calculations could be made to determine the water use just for production
and exclude all other operations.
2.2.2 Life Cycle Inventory
The life cycle inventory considers all of the necessary inputs and outputs that occur
during the life cycle of the product. The process data were collected directly from Flourish
Farms owners and within the detailed records of produce and fish species output, fish food
input into the system, pest management use, electrical use, water bills, natural gas
consumption, and necessary equipment for operational activity. The life cycle inventory
shows all of the inputs into the system in order to produce 1 kg of lettuce and 1 kg of fish
(Table 3).
37
Table 3. Life Cycle Inventory of Flourish Farms.
Inputs Value UnitsLCI of 1 kg fish Fish feed 0.69 Kg
Pesticide production 0.0332 KgMarket for tap water 272 KgMarket for electricity 0.00843 mW hMarket for natural gas 4.83 kg
LCI of 1 kg lettuce Fish feed 0.054 KgPesticide production 0.00259 KgMarket for tap water 130 KgMarket for electricity 0.00365 mW hMarket for natural gas 4.83 KgTransport to costumer 4,970 kgkm
These values correspond to the process flows created within the GaBi V5.0 software (Fig.
13 & 14).
Figure 13. Life Cycle Assessment Process Flow for Fish. This image, taken from GaBi V5.0
software, exhibits the inputs into the database for the production of 1 kg of fish from the
farm.
38
Figure 14. Life Cycle Assessment Process Flow for Lettuce. This image, taken from GaBi
V5.0 software, exhibits the inputs into the database for the production of 1 kg of lettuce from
the farm.
These values were calculated from monthly utility meter readings of the natural gas and
water use. Additionally, electrical consumption was calculated from the kWh operational
data listed on each piece of equipment for the foreground analysis. The operational
equipment background data was excluded from this study. The building uses equipment to
control temperature, humidity, lighting, and water flow. These include five horizontal airflow
fans, two vent fans, a wet wall pump, circulation pump, four HID metal halide lights,
intermediate bulk container power pumps, a main MDM Inc. ValuFlo 6100 water pump
(Colorado Springs, CO), two media bed water pumps, an NFT pump, three nursery pumps,
one tower pump, and an S31 regenerative air blower. The system also uses fish tank boilers,
known as ‘fish sweaters’ and two Modine heaters (Racine, WI) to heat the water and
greenhouse respectively. Each piece of electrical equipment was evaluated for the average
hours per day it would run, and seasonal variation was calculated as well (Table 4).
39
Table 4. Electrical Operational Equipment at Flourish Farms. The following equipment was
all researched for kilowatt hour capacity, seasonal use, daily use, and number of units. This
combined information was used to calculate the total kilowatt requirements for the farm, and
was then converted into megaJoules for the EU factor for this study.
Component Units kWh Watts OperationalHours
OperationalDays
HAF Fans 5 0.575 115 23 120Modine Heaters 2 0.250 125 4 365Vent Fan A 1 0.560 560 4 365Vent Fan B 1 0.560 560 2 365Wet Wall Pump 1 0.060 60 0 120Circulation Pump 1 0.006 16 0 120HID Metal Halide Lights 4 1.600 400 6 120IBC tower pump 1 0.145 145 0 365ValuFlo 6100 Water Pump 1 0.207 207 24 365Media Bed Water Pump 1 0.058 58 24 365Media Bed Water Pump 1 0.033 33 24 365NFT Pump, Model 18B 1 0.145 145 0.5 365Nursery Pump 1 1 0.138 138 0.5 365Nursery Pump 2 1 0.104 104 0.5 365Nursery Sump Pump, Model 18B 1 0.180 180 0.5 365S31 Blower 1 0.471 471 24 365Tower Pump 1 0.070 70 24 365
These values were summed to produce the total kWh the farm uses in one year. This
value was converted into megaJoules for this study, and reported as the EU. Additionally,
having this inventory analysis of the operational equipment allows the end user to highlight
which machinery contributes the most to the environmental impact.
In order to calculate the GWP, the cubic feet of compressed natural gas used in the
Modine heaters and aquaponic hot water heaters where converted into kilograms of CO2
production using equations in the Chemistry of the Elements (Greenwood & Earnshaw,
1997). The CO2 emissions (calculated from kg/km) for the transportation to Flourish Farm’s
40
customer base were also added into the GaBi V5.0 software. These values were then divided
by the total kilograms of lettuce and fish to produce the kg CO2 e/kg value. The kg CO2 e/kg
emissions from the electrical components of the system, lights, fans, heaters, and pumps,
were included into the total GWP calculation as well.
The WD data were collected using meter pulls from Denver Water for the farm within the
GrowHaus through 2014. These data include all water used by the farm, not just what would
be inserted into the system to replace daily evaporation and transpiration. However, the
majority of water use at the farm is used for replenishing water lost from transpiration, plant
mass growth and evaporation.
Flourish Farm obtains its Pond Low-Energy fish feed from Skretting USA, a Nutreco
company. LCA data were obtained from the Skretting Australia Annual Sustainability Report
(2014), a cradle to gate LCA analysis, which was incorporated into the study to account for
GWP, EU and WD for the farm’s fish feed input. Eutrophication data were not included in
the sustainability report. To date, an LCA has not been completed for the U.S. site, so the
data from the Australia facility were used as a close comparison. The products components
are listed in Figure 15.
Figure 15. Skretting’s Pond LE fish feed components. Flourish farms uses the 5.5mm
floating size (www.skrettingusa.com/products/pond-diet).
41
The transportation greenhouse gas emissions were calculated using a list of the delivery
locations and frequency reporting from the farm. Flourish Farms delivers their own produce
and all fish are sold at the GrowHaus facility. In order to calculate the average delivery
weight, nine deliveries were categorized into product type and weighed, and then that
average was used for other calculations. The optimal route was computed using Google’s
OptiRoute by inserting the 21 delivery locations (Fig. 16; Appendix A). This route was not
used by Flourish Farms every week, as errands and deliveries varied, but is an average
approximation for the year. The mileage for each trip from OptiRoute was multiplied across
the number of deliveries per year to obtain the total mileage for 2014.
42
Figure 16. Flourish Farms delivery route. Flourish Farms delivers to 20 businesses in the
surrounding Denver area. Each trip is 24.3 miles round trip, and the deliveries are taken twice
a week. See Appendix A for delivery locations.
Although the aquaponic farm used eight various integrated pest management techniques
(Appendix C), none of these were available in the GaBi V5.0 database. Conversely, a generic
“pesticide production” database was available, which was used for this study. Flourish
Farm’s pest management focuses on low environmental impact products, and the GaBi V5.0
database option does not include this. As a result, the environmental impact from the pest
management may reflect slightly higher outcomes than the actual pesticides used would
represent. However, the pest management is a minor input category, so the effects from this
discrepancy are not considered to be significant.
43
The aquaponic farm contains many capital components in order to run at a commercial
scale. Although the background data from these components were not included in this LCA,
the infrastructure is listed in Table 5 in order to gain an understanding of the scale and space
required for this facility to operate.
Table 5. Necessary infrastructure in Flourish Farm’s aquaponic system. The following
materials are the entire main infrastructure in Colorado Aquaponic’s farm.
Component Volume (m3) Dimensions (m)
Raft Bed 1(Media and DWC) 7.86 1.22 W x 23.16 L
Raft Bed 2 DWC 7.86 1.22 W x 23.16 L
Raft Bed 3DWC 5.76 1.22 W x 7.92 L
Raft Bed 4 DWC 11.52 2.44 W x 23.16 L
NFT Pumps - 30.48 L
Wood Fish Tank 2.03 0.92 W x 3.35 L x 0.61 Deep
Main Fish Tank 3.18 2.29 Diameter x 1.02 Deep
Blue Tank (Cone Bottom) 1.76 1.57 W x 1.57 L x 0.71 Deep
Brush Filtration Tank 0.68 0.66 H x 1.35 L x 0.94 W
Clarifier Filter (Cone Bottom) 0.45 0.71 Diameter x 1.47 H
The main infrastructures are four raft beds (three DWC, and one with both DWC and
media), 30m of NFT, a 2m3 wooden fish tank for younger fish, a 3m3 main tank for mature
fish, and a 1.76m3 cone bottom tank. There are also two filtration systems to remove solids
from the effluent in order to prevent waste accumulation and root damage. The entire system
is housed in a repurposed greenhouse that was constructed in the 1970s. The greenhouse was
renovated to be a growing environment in 2012 (JD Sawyer personal communication, 2016).
2.2.3 Life Cycle Impact Assessment
The impact assessment calculates the GWP, WD and EU use based off of the values from
the inventory analysis. A life cycle impact assessment then transfers the emissions and
resource data into indicators that reflect environment and health pressures as well as resource
44
scarcity (ILCD, 2011). This required a four step process (1) allocating the resources to the
two co-products within the system, (2) calculating the total gas use, water use and electricity
use produced by each process, and (3) converting the gas use into CO2 equivalency (CO2 e)
for the GWP calculation, converting the electricity use into mJ, and converting the water use
into m3, as all of these are the standard unit for comparison in LCA studies.
Allocation. Allocation is a partitioning practice used to divide the input or output flows
of a process between two or more product systems (ISO, 14044). Since the farm has the co-
products of fish and various produce from the same resources, the input data were allocated
to two categories of production using economic profits, as practiced by other aquaculture
LCA studies (Ayer et al., 2008). This resulted in 16.3% of the resources contributing to the
aquaculture production, and 83.7% of the resources to the lettuce production. From these
allocations, two separate LCAs were completed. One using 16.3% of all resource use
allocated to aquaculture production, and the second using 83.7% of resource use allocated to
lettuce production. This allocation also allowed the LCA results of the fish production in
aquaponics to be approximate compared to literature values of LCAs for aquaculture, and the
LCA results of the lettuce production in the aquaponic system to be compared to traditional
agriculture and hydroponic lettuce production.
Total Resource Use. The inventory analysis was inserted into GaBi V5.0 in order to
calculate the GWP, WD and EU for the aquaponic system for 1 kg of lettuce and 1 kg of fish
production. The input and output data were linked to EcoInvent and U.S. Life Cycle
Inventory databases in GaBi V5.0. These databases contain data on materials, emissions and
energy consumption for the manufacture of one unit of production.
Conversion. Once the inputs are linked to the correct databases, GaBi V5.0 software
converts the input unit into the output unit, based on the background database information.
45
For the GWP conversion, all of the emissions calculations are completed for the electricity
use, natural gas use, transportation, and water acquisition. The GWP also included the
emissions used to engineer the fish feed and integrated pest management. The software
automatically completes any necessary conversion required to account for greenhouse gases
that have varying global warming potencies into a standard of 1 kg of CO2. For instance,
according to the IPCC CH4 has a global warming potential that is 21 times higher than CO2
over 100 years (IPCC, 1996). The water dependency was converted from kg of water into m3
and incorporated the water used on the farm, as well as the water dependency used for fish
feed and the pesticide. The EU for this study was hand calculated, using the conversion
factor of 1 kWh to 3.6 megaJoule (mJ), as the GaBi V5.0 software did not report this metric.
The International Reference Life Cycle Data System (ILCD) analysis was used as the impact
assessment method for this study. The ILCD published the ‘Recommendations for Life Cycle
Impact assessment in the European Context’ which chooses the methodology for each impact
category that has been evaluated as the best (ILCD, 2011). Although the Tool for the
Reduction and Assessment of Chemical and other environmental Impacts (TRACI 2.1),
developed by U.S. Environmental Protection Agency (EPA), can have more contextual
significance for a study done in the U.S., TRACI did not include any metrics on water
dependency, whereas the ILCD LCIA does include this as an impact category, which was
important for this study. The process flows for the lettuce and fish LCIA are shown in
Figures 13 and 14.
2.3 Results
Flourish Farms used a total of 14,157 kg of CO2 equivalency in order to produce 2,700 kg
of lettuce and 252 kg of fish in 2014. The total 2014 EU for the system was 33,670 mJ, and
the WD was 420 m3 for all operations. Flourish Farms had zero material waste, as all solids
46
removed from the clarifier filter were mixed into a fertilizer solution for use in soil based
gardens, lawns, compost and foliar sprays within the GrowHaus. All roots from the
vegetables were either sold with the product, or trimmed and used in composting bins. The
farm used a total of 0.74 kg of fish feed per kg of combined fish and lettuce production and
the farm used 0.04 kg of integrated pest management per kg of production. Flourish Farm
delivered 307 kg of produce to their customers, with 4084 kilometers driven throughout the
year, from a twice weekly delivery schedule. This accounts for the 13.3 kilometers per
kilogram of lettuce delivered. The farm currently sells or donates the remaining 89% of their
produce and 100% of their fish within the GrowHaus.
This aquaponic system had a GWP of 12.95 kg CO2 e/kg, which combines the LCA
analysis of the fish and lettuce (Fig. 17 & 18, respectively). The EU for the farm totaled
32.38 mJ/kg, and the WD was 0.1945m3/kg (Table 6). The GWP is 63% from the electric
requirements, 26% from the natural gas use, 6% from transport to customers, and the
remaining 5% was attributed to the pest management, tap water acquisition and fish feed
(Fig. 19).
47
Figure 17. Global warming potential of fish production at Flourish Farm.
8.5
0.00345
2.26
5.675
0.187 0.376
0
1
2
3
4
5
6
7
8
9
Total Fish Feed Natural Gas Electric Tap Water Integrated PestManagement
GW
P(k
gC
O2
e/k
gof
fish
)
Inputs to the Farm
48
Figure 18. Global warming potential of lettuce production at Flourish Farms.
Table 6. The total global warming potential (kg CO2 e), energy use (mJ) and water
dependency (m3) for Flourish Farm lettuce and fish per kilogram in 2014.
Mass
Produced
(kg)
Units
Produced
Economic
Allocation
(%)
GWP
(kg CO2 e/kg)
EU
(mJ/kg)
WD
(m3/kg)
Fish 252 1,685 16.3 8.50 21.77 0.1350
Lettuce 2,700 30,553 83.7 4.45 10.44 0.0595
Total 2,952 32,238 100 12.95 32.38 0.1945
4.45
0.000162
1.08
2.454
0.0895 0.0294
0.786
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
Total Fish Feed Natural Gas Electric Tap water IntegratedPest
Management
Transport
GW
P(k
gC
O2
e/k
gof
lett
uce
)
Inputs to the Farm
49
Figure 19. Distribution of global warming potential kg of CO2 e/ kg of production within
Flourish Farms.
The results from this study were then compared with results from the literature in order to
evaluate the environmental costs of aquaponics contrasted to hydroponic systems,
aquaculture systems and traditional agriculture.
In order to compare the lettuce production from aquaponics to hydroponics and
traditional agriculture, the resource allocation of 83.7% was used. The allocation percentage
was applied to each resource input into the farm for the lettuce LCA. The lettuce production
in the aquaponic system had a higher yield than irrigated traditional agriculture by 18.12
kg/m2, and a lower yield than hydroponics by 18.98 kg/m2. The GWP of aquaponics was
4.45 kg of CO2 e/kg, higher than both hydroponics and irrigated traditional agriculture, which
Fish Feed~0% Natural Gas
26%
Electric63%
Tap Water2%
PestManagement
3%
Transport6%
50
were 0.90 and 0.86 kg of CO2 e/kg respectively. The data indicated that aquaponics had a
lower WD than irrigated traditional agriculture by 0.19 m3/kg, but a higher WD than
hydroponics by 0.04 m3/kg. EU was the highest in hydroponic systems, with aquaponics
lower by 79.42 mJ/kg. Aquaponics had a higher EU than traditional agriculture by 9.48
mJ/kg. The rain fed agriculture had a 21.89 kg/m2 lower yield than aquaponics. However,
rain fed agriculture also had the lowest GWP when compared to all other farming systems.
The WD of rain red agriculture was 0.02 lower than aquaponics, and 0.02 higher than
hydroponics. EU calculations were not available in the Hall et al 2014 study (Table 7).
Table 7. Comparative of annual land use, water dependency and energy use in aquaponics,
hydroponics and traditional agriculture for 1 kilogram of lettuce production. The aquaponic
data for this comparison used the 83.7% allocation of resources use to represent only the
lettuce production component of the system.
The fish production of aquaponics was then compared to various aquaculture LCA
studies, using the 16.3% allocation of resources. The allocation percentage was applied to
each resource input into the study for the fish LCA. This study indicated that aquaponics had
a slightly higher GWP compared to other aquaculture systems, except for the arctic char
Agricultural TypeYield
(kg/m2)
GWP
(kg of CO2
e/kg)
WD
(m3/kg)
EU
(mJ/kg)Reference
Aquaponics 22.02 4.45 0.06 10.58 Current study
Hydroponics 41.00 ± 6.10 0.90 0.02 ± 0.01 90.00 ± 11.00
Barbosa et al 2015
Rothwell et al 2016
Traditional
Agriculture Irrigated 3.90 ± 0.21 0.86 0.25 ± 0.03 1.10 ± 0.08
Barbosa et al 2015
Plawecki et al 2015
Traditional
Agriculture Rain fed 0.13 ± 0.08 0.21 ± 0.12 0.04 ± 0.04 - Hall et al 2014
51
recirculation system (Ayer & Tyedmers, 2009). While the Bainbridge (2012) and Boxman
(2016) aquaponic study showed a mid-range EU, this study’s aquaponic system had the
lowest EU of all systems. All aquaponic systems had the lowest WD compared to all other
aquaculture types (Table 8).
Table 8. Comparison of Global Warming Potential, Energy Use, and Water Dependency of
various aquaculture systems with values in terms of one kilogram of fish production. The
aquaponic data for this comparison used the 16.3% allocation of resource use to represent
only the aquaculture production component of the system.
Fish Type System Type
GWP
(kg CO2
e/kg)
EU
(mJ/kg)
WD
(m3/kg)Reference
Tilapia & HSB Temperate Aquaponics 8.50 21.79 0.135 Current Study
Tilapia Temperate Aquaponics 7.18 121.25 0.01 Bainbridge 2012
Tilapia Tropical Aquaponics 9.52 123.46 -1.50 Boxman et al 2016
Turbot Recirculation 6.02 290.99 4.81 Aubin et al 2006
Rainbow trout Flow through 2.02 34.87 98.80 Roque d'Orbcastel et al 2009
Rainbow trout Flow through 2.75 78.23 52.60 Aubin et al 2009
Rainbow trout Recirculation 2.04 63.20 6.63 Roque d'Orbcastel et al 2009
Seabass Net pen 3.60 54.66 48,720.00 Aubin et al 2009
Arctic Char Recirculation 28.20 353.00 - Ayer and Tyedmers, 2009
Atlantic Salmon Net Pen 2.07 26.90 - Ayer and Tyedmers, 2009
2.4 Discussion
2.4.1 Impact Assessment
The field of aquaponic farming has been rapidly growing over the past decades, but there
have been very few rigorous, peer-reviewed systems research published on the topic.
Because of this, assessment of these systems is needed in order to provide stakeholders
information on the benefits and costs of aquaponics and the potential these systems have for
providing sustainable food production. In a study done by Farahipour et. al., (2014) LCA has
52
been shown to be capable of producing some nontrivial results that can be significantly
helpful when it comes to decision making. This LCA demonstrated that aquaponics has
beneficial reductions for some environmental impacts associated with food production, but it
has a higher impact in other categories. Aquaponics showed a great potential for increasing
yield per land area, while decreasing water use compared to conventional agriculture. The
lettuce production in aquaponics was also outperformed by hydroponics in regards to yields
and water use. However, this aquaponic system used less energy than the comparative
hydroponic studies from the Barbosa et al., study (2015). This study used data focusing on
agricultural practices in Arizona, US as 29% of lettuce production nationwide occurs in this
state (Barbosa et al., 2015). The conventional agriculture ranges were determined from an
“order of magnitude” study from Acker et al. (2008) that focused on the required energy and
water for all lettuce cultivation in Arizona (as well as other crops). The hydroponic data
from the Barbosa et al. (2015) study was from an enterprise model from the Ohio State
University, used to estimate the revenue, expenses, and profitability associated with
greenhouse lettuce production. Data was also taken from two more hydroponic studies to
estimate water and energy use. These comparative studies for hydroponics and traditional
agriculture in Arizona have a warmer climate than Denver, Colorado. In order to compare
how sustainable aquaponics is as a local food production system for this city, it would be
helpful to compare to agricultural systems within this state, which so far, have not been
completed. Rain fed agriculture, in comparison, had much lower yields than any other
production type. However, they had a corresponding low GWP value as well. Although
primarily rain fed, the farmers in the Hall et al., study did supplement with irrigation when
needed, which resulted in the slightly higher WD than hydroponics. The rain fed agriculture
WD was still lower than irrigated traditional agriculture and aquaponics. In regards to fish
53
production, aquaponics contributed more to GWP than all other types of aquaculture except
for an arctic char recirculation system (Ayer & Tyedmers, 2009). However, the EU and WD
for this aquaponic study was the lowest of all aquaculture systems, which has the potential
for natural resource conservation. The comparison between temperate and tropical
aquaponics shows that regardless of the climate, the GWP is still high for the production.
This is potentially from the University of Virgin Islands system focusing primarily on fish
production, while Flourish Farms primary product is lettuce. The Boxman et al., (2016) study
also used the basil production as a credit to their system, instead of using an additional
functional unit. This resulted in several avoided products, which is why there is a negative
WD for this system. However, the water additions for the Boxman system were 0.16 m3/kg,
which was 0.03 m3/kg higher than Flourish Farms. These comparisons suggest that although
it would be logical to assume gained production efficiencies from a tropical climate system
that does not need a greenhouse, this is not necessarily the case.
This study identified areas where efficiencies could be built into aquaponics in order to
have a more sustainable system. The GWP for aquaponics was higher than other agricultural
systems, and could be reduced by the farm considering alternative energy solutions, such as
purchasing wind energy from their source. The farm currently has plans to install solar panels
which will reduce both the GWP and the EU for the system. Presently 63% of Flourish
Farms GWP is from the electrical usage of the farm, and 26% from the natural gas
consumption, so this improvement could help reduce these electrical usage components from
the farm. One of the hot-spots for electrical consumption was the use of the halide lights for
six hours a day during the winter. In the future, converting to LED lights could reduce energy
use for this component by 60%, although the greater capital cost for the lights would need to
be considered. Part of this high natural gas consumption comes from the temperate
54
continental climate, which generates hot summers and very cold winters, requiring high
temperature mediation. The aquaponic water culture is kept consistently between 21ºC and
22.7ºC, and the greenhouse air temperatures range from 12.7 to 23.8ºC. This amount of
temperature control in a drastically changing climate in Colorado is energy intensive to
maintain. Another aspect to consider is the building where Flourish Farms is located is in a
repurposed historic greenhouse from the 1970s, which lacks modern infrastructure to more
efficiently retain heat. Solar thermal heating and water heating could be applied to the
building to reduce the GWP, as well as a climate battery, which could store hot air
underground to use during the cold weather. One advantage aquaponics has in comparison to
traditional agriculture is the local customer base. Flourish farms sells and delivers all of its
products within an 8 kilometer radius. One of the potential reasons that the GWP for
aquaponics exceeded that of traditional agriculture is the reliance on electricity and heat for
the system to operate. While conventional farms do irrigate and have machinery for tilling,
weeding and harvesting, rarely are all of these components operating twenty-four seven. In
an aquaponic system the water pumps, circulators, aerators, and heating or cooling
mechanism need to be on one hundred percent of the time. If one of these elements were to
fail, there would likely be a large fish die-off, as there was in this farm when the generators
failed. However, the benefit from the constant circulation is the increased yield and year
round production, which many Midwestern agricultural systems cannot offer.
During the course of this study, Flourish Farms harvested both tilapia and HSB. HSB was
thought to be beneficial because it can be raised in lower water temperatures than tilapia, and
therefore saving on water heating costs. However, tilapia and HSB both grow optimally from
23ºC to 27ºC. Flourish Farms typically kept water temperatures 1 to 2ºC lower than
optimally growing records. One recommendation was to reduce the water temperature further
55
while the HSB were the primary species, since they are more resilient under cold conditions
than tilapia. Flourish Farms actually did attempt this growing technique to reduce GHG and
heating costs. They lowered water temperatures to 10ºC and found that the HSB were still
sustained. However, because the reduced temperatures slowed the HSB growth, the
nitrification process slowed as well, doubling the amount of time for the lettuce production to
reach harvest size. The reduction in profit harvestable vegetables was actually far greater
than the costs saved in heating over the winter.
While the WD for aquaponics was lower than traditional agriculture and aquaculture, it
was still higher than the projected 10% of water usage of traditional agriculture that many
studies support (Somerville et al., 2014; Lennard & Leonard, 2006; Bainbridge, 2012). This
LCA indicated that aquaponics uses 24% less water than traditional irrigated agriculture and
in a desert climate. Flourish Farms going forward should carefully track where water is being
applied in the system, and look for any possible reductions. Another possible reduction is
Denver approved rainwater collection in 2015, which could be another water source the farm
could utilize instead of tap water (Gauldin, 2015). The Bainbridge aquaponic LCA predicted
that a 0 m3 WD could be achieved in their system by relying on rainwater collection alone
(2012). The farm also experienced several operational emergencies during 2014, which could
have caused a need for the system to be flushed and heavy water use during this time.
Additional years of data and notes of future notes of high water usage may prove that 2014
was an outlier in WD for Flourish Farms.
The lettuce yield for aquaponics shows promise as the production was 560% higher than
traditional irrigated agriculture and 16,838% higher than rain fed agriculture. Higher yields
can result in more effective land use planning and management, which will become
56
important as we continually try to feed more people with less space. Land that is saved from
intensive agriculture could be use for conservation, which could improve the environment.
Some points of consideration for this study that may contribute to uncertainty in the
results, is Flourish Farms, up until recently, did not weigh their fish. The method for sales
included estimating fish length at approximately 12.7 cm long or “plate size” and selling the
fish for an even five USD. Typical aquaculture studies meticulously weigh the protein
produced and sell the fish by weight which gives very accurate production numbers, instead
of the estimates used in this study. The farm also experienced a dramatic die-off during the
2014 year in which 491 fish died due to loss of electricity. In order to account for this die off,
this study added these fish weights into the protein produced, even though this protein was
not sold.
Additionally, many studies use the DM value of plant mass as a better indication of the
actual production. DM does not include the water accumulated while growing, and therefore
has a greater consistency than WM. As water has no nutritional components, it is not ideal to
use the water weight within the product as part of the production. However, since the data for
this study were taken from 2014 Flourish Farms had already weighed their products before
the viewing of the data and any alterations could occur. One recommendation for future data
collections would be to have DM values for each product that the farm is selling, in order to
have more accurate measure of the food produced. Another data collection recommendation
would be to have consistency in the metrics that are being collected. Not all data points in all
years had consistent utility readings or fish counts. Other helpful metrics would be daily
water temperature readings, air temperature readings, and more precise recordings of
equipment operation throughout the year.
57
One issue with comparing LCA results to other LCA literature studies is that rarely will
the study boundaries reflect the same exact inclusions and exclusions. Each LCA is
completed with individual goals, and therefore the studies can be difficult to compare equally
as some studies will include more of the process than others. This is a concern for this study
as some of the literature values, (e.g. Barbosa et al., 2014) used fewer production
components than this study, while others (e.g., cradle to grave aquaculture studies) used more
production and life cycle events than this study. Unfortunately, without completing a range
of LCA studies compromising of various study boundaries this issue cannot be avoided.
LCAs will usually only compare if the two systems analyses were completed by the same
researcher, so the variable for the study boundary will be consistent. In order to account for
this discrepancy, the values for this study are primarily used for the farm’s benefit, and not as
concrete comparative value. A confidence variation analysis could help to make the
comparisons more effective.
Additionally, the allocation methods for this study could be improved since the economic
production required some estimation in regards to fish weights and sales. A method involving
resource requirements or mass for each subcategory of production may generate better
allocation percentages and will be considered for future research. Ultimately, better systems
information will quantitatively address hypotheses about the relative efficiencies of
aquaponic vs. other alternative farming techniques.
Local year-round food production is becoming increasingly important to communities
looking to have higher food security and food sovereignty, and aquaponics is a mechanism
that communities can explore. LCA’s can help individuals and communities evaluate if this
food production system is the right fit for the goals they hope to achieve.
58
2.5 Conclusions
This study has shown that aquaponics possesses certain environmental benefits as
compared to other agriculture systems. If applied on a larger scale, aquaponics could have
significant positive environmental impacts on the food system. This production system also
shows promise in international development to increase access to affordable protein when
there are limited options available. This research demonstrated that there may be ways to
produce high quality protein and produce, that has potential to be less environmentally
wasteful and costly than traditional agriculture, hydroponics and aquaculture. Further
investigation and implementation of alternative food systems could be a step in increasing
local food production, and shifting away from the industrial global food market.
59
REFERENCES
Acker T., Atwater C., French W., Glauth M., Smith D. 2008. Energy and Water Use inArizona Agriculture, Working Paper 08–08. Northern Arizona University. Availableat http://franke.nau.edu/images/uploads/fcb/08-08.pdf. Accessed on 30 November 2016.
Akundi, A. 2013. GaBi Hand Dryer Tutorial. University of Texas, El Paso. Available athttp://academics.utep.edu/Portals/3341/GaBi%20Tutorial%20GEM%20class%202013_Finalized.pdf. Accessed 30 November 2016.
Al-Hafedh Y.S, Alam A., and Beltagi M.S. 2008. Food Production and Water Conservationin a Recirculation Aquaponic System in Saudi Arabia at Different Ratios of Fish Feed toPlants. Journal of World Aquaculture Society 39(4):510 – 520.
Aubin, J., Paptryphon, E., van der Werf, H., and Chatzifotis, S. 2009. Assessment ofenvironmental impact of carnivorous finfish production systems using life cycleassessment. Journal of Cleaner Production 17(3). p 354.
Aubin, J., Papatryphon, E., Van der Werf, H., Petit, J., and Morvan, Y. 2006.Characterization of the environmental impact of a turbot (Scophthalmus maximus) re-circulating production system using Life Cycle Assessment. Aquaculture 261(4). pp1259–1268.
Ayer, N., Tyedmers, P., Pelletier, N., Sonesson, U., and Scholz, A. 2008. Co-productallocation in lifecycle assessments of seafood production systems: review of problemsand strategies. International Journal of Life Cycle Assessment 12(7). pp 480–487.
Ayer N., Tyedmers P. 2009. Assessing alternative aquaculture technologies: life cycleassessment of salmonid culture systems in Canada. J Clean Prod 17. pp 362–373. doi:10.1016/j.jclepro.2008.08.002.
Barker, A.V. & Pilbeam, D.J. 2007. Handbook of Plant Nutrition. CRC Press, 4. Available athttps://books.google.com/books?id=5k0afN5UZ4IC&pg=PA4#v=onepage&q&f=false .Accessed on 10 October 2015.
Bainbridge, R. 2012. Life Cycle Assessment of an Aquaponics Greenhouse. University ofStirling. Accession Order No. [1721906].
Barbosa, G.L., Gadelha, F.D., Kublik, N., Proctor, A., Reichelm, L., Weissinger, E.,Wohlleb, G.M., and Halden, R. 2015. Comparison of Land, Water, and EnergyRequirements of Lettuce Grown Using Hydroponic vs. Conventional AgriculturalMethods. Int J Environ Res Public Health 12(6). pp 6879-6891.
Barrett G.W., and Odum E.P. 2000a. The Twenty-First Century: The World at CarryingCapacity. BioScience 50(4). pp 363–68.
Bernstein, S. 2011. Aquaponic Gardening: A step-by-step guide to raising vegetables andfish together. New Society Publishers, Canada.
Brownlee M. 2013. Local food shift: Thinking like a foodshed. Transition in Colorado.
60
Boxeman, S.E., Zhang, Q., Bailey, D., and Trotz, M.A. 2016. Life cycle assessment aCommercial-Scale Freshwater Aquaponic System. Environmental Engineering Science.November 2016, ahead of print. doi:10.1089/ees.2015.0510
Clean Water Act. 2002. Clean Water Act of 1972, 33 U.S.C. § 1251 et seq. Available athttp://epw.senate.gov/water.pdf. Accessed on 17 November 2016.
Coche, A.G. 1967. Fish culture in rice fields: a world synthesis. Hydrobiologia 30(1): pp 1 -44.
Cran Communications. 2015. Zip Codes with the Highest Percentage of Population BelowPoverty Level in Colorado. Zip Code, Area Code, City & State Profiles | ZipAtlas. CrainCommunications Inc. Available at http://zipatlas.com/us/mi/city-comparison/unemployment-rate.htm . Accessed on 10 October 2015.
Crossley, P.L. 2004. Sub-irrigation in wetland agriculture. Agriculture and HumanValues. 21(2/3): pp 191–205. doi:10.1023/B:AHUM.0000029395.84972.5e. Accessed on30 November 2016.
Dutko P., Ver Ploeg M., Tarrigan, T. 2012. Characteristics and influential factors of fooddeserts. ERR-140, U.S. Department of Agriculture, Economic Research Service.
Edenhofer, O., Pichs-Madruga, F., Sokona, Y., Farahani, E., Kadner, S., Seyboth, S., Adler,Baum, I., Brunner, S., Eickemeier, P., Kriemann, B., Savolainen, J., Schlömer, S., vonStechow, C., Zwicke, T., and Minx, J.C. 2014. IPPC: Summary for Policymakers in:Climate Change 2014: Mitigation of Climate Change. Working Group III to the FifthAssessment Report of the Intergovernmental Panel on Climate Change. CambridgeUniversity Press, Cambridge, United Kingdom and New York, NY, USA.
Energy Information Association. 2016. Monthly Energy Review. Table A4, ApproximateHeat Content of Natural Gas for End-Use Sector Consumption. Available fromhttps://www.eia.gov/totalenergy/data/monthly/pdf/sec13_4.pdf. Accessed 27 January2016.
Engel, E. 2013. Starting up and maintaining an aquaponics system. Visueel Journalist. PreziPresentation. Amsterdam. Available at https://prezi.com/1sfna-2dpvwf/starting-up-and-maintaining-an-aquaponics-system/. Accessed on 17 November 2015.
Environmental Protection Agency. 2012. Effluent Guidelines – Aquatic Animal ProductionIndustry. United States Environmental Protection Agency. Available athttp://water.epa.gov/scitech/wastetech/guide/aquaculture/fs-final.cfm. Accessed on 27January 2016.
Environmental Protection Agency. 2015. Inventory of U.S. Greenhouse Gas Emissions andSinks:1990-2013. Annex 2 (Methodology for estimating CO2 emissions from fossil fuelcombustion), Table A-40. U.S. Environmental Protection Agency, Washington, DC.U.S. EPA #430-R-15-004. Available athttp://www3.epa.gov/climatechange/ghgemissions/usinventoryreport.html. Accessed on10 August 2016.
61
Environmental Protection Agency. 2016. State Progress Toward Developing NumericNutrient Water Quality Criteria for Nitrogen and Phosphorus. U.S. EnvironmentalProtection Agency. Available at https://www.epa.gov/nutrient-policy-data/state-progress-toward-developing-numeric-nutrient-water-quality-criteria. Accessed on December 5th,2016.
European Union. 2011. European Commission-Joint Research Center – Institute forEnvironment and Sustainability: International Reference Life Cycle Data System (ILCD)Handbook – Recommendations for Life Cycle Impact Assessment in the EuropeanContext. First Ed. Eur 24571 EN., Luxemburg.
Gauldin, A. 2015. Rooftop rainwater collection bill easily clears Colorado committee.Denver Post. March 16, 2015. Available athttp://www.denverpost.com/2015/03/16/rooftop-rainwater-collection-bill-easily-clears-colorado-committee/. Accessed on 16 June 2016.
Goedkoop, M., Oel,e M., Leijting, J., Ponsioen, T., Meijer, E. 2013. Introduction to LCAwith SimaPro. SimaPro. Available from https://www.presustainability.com/download/SimaPro8IntroductionToLCA.pdf / Accessed on Novermber13, 2015.
Greenwood, N.N., & Earnshaw A. 1997. Chemistry of the elements. Butterworth,Heinemann. Oxford.
Hall, G., Rothwell, A., Grant, T., Isaacs, B., Ford, L., Dixon, J., Kirk, M., and Friel, S. 2014.Potential environmental and population health impacts of local urban food systems underclimate change: a life cycle analysis case study of lettuce and chicken. Agriculture andFood Security, 3(6). Doi:10.1186/2048-7010-3-6
Fankuchen P.A. 2013. The Case for Aquaponics: an Environmentally and EconomicallySuperior Method of food Production. CMC Senior Theses. Paper 735.http://scholarship.claremont.edu/cmc_theses/735
Farahipour, R., and Karunanithi, A.T. 2014. Life cycle environmental implications of CO2
capture and sequestration with ionic liquid 1-butyl-3methylimidazolium acetate. ACSSustainable Chem. Eng., 2, pp 2495-2500. Doi: dx.doi.org/10.1021/sc400274
Fisher, S. 2014. A case study of urban agriculture: a life cycle assessment of vegetableproduction. University of Colorado Denver dissertation.
Food and Agriculture Organization. 2016. Fishery Statistical Collection. Global AquacultureProduction. Food and Agriculture Organization of the United Nations. Fisheries andAquaculture Department. Available at http://www.fao.org/fishery/statistics/global-aquaculture-production/en. Accessed 30 November 2016.
Feedstuffs. 2014. Aquaponics Enables Urban Fish Fanning. April 28. AcademicOneFile. http://go.galegroup.com/ps/i.do?id=GALE%7CA367299107&v=2.1&u=auraria_main&it=r&p=AONE&sw=w&asid=722427a3044598799d02bc3901e99c6b.
Hazell, P.B.R. 2009. The Asian Green Revolution. International Food Policy ResearchInstitute Discussion Paper 00911. International Food Policy Research Institute. Available
62
at https://books.google.com/books?id=frNfVx-KZOcC&pg=PA1#v=onepage&q&f=false. Accessed on 30 November 2016.
International Organization for Standardization. 1997. ISO 14040, EnvironmentalManagement – Life Cycle Assessment – Principles and Framework. Geneva.
International Organization for Standardization. 2006. ISO14040:2006 – EnvironmentalManagement – Life Cycle Assessment – Principles and Framework. Geneva.
International Panel on Climate Change. 2006. 2006 IPCC Guidelines for NationalGreenhouse Gas. Inventories. Intergovernmental Panel on Climate Change, Geneva,Switzerland. [Online] Available from http://www.ipcc-nggip.iges.or.jp/public/2006gl/index.htm. Accessed on 10 August 2016.
Kreissig, J., Baitz, M., Kummel, J. 1997. Life Cycle Engineering for the Architect –Environmental rating of structural components with reference to the entire system.University of Stuttgart.
Lennard W.A., and Leonard, B.V. 2006. A Comparison of Three Different Hydroponic SubSystems (gravel Bed, Floating and Nutrient Film Technique) in an Aquaponic TestSystem. Aquaculture International 14(6). pp539–50. doi:10.1007/s10499-006-9053-2
Lovatelli, A. 2015. Technologies and practices for small agricultural producers: designing anaquaponic unit. Aquaculture Branch of the Fisheries and Aquaculture Policy andResource Division. Food and Agricultural Organization of the United Nations. Availableat http://teca.fao.org/read/8350. Accessed on 5 December 2016.
Love D., Fry J., Genello L., Hill E., Frederick J., et al. 2014. An International Survey ofAquaponics Practitioners. PLoS ONE 9(7). e102662. doi:10.1371/ journal.pone.0102662
McCollow K. 2014. Aquaponics Revives an Ancient Farming Technique to Feed the World;A Converted Minnesota Brewery Now Combines Hydroponics and FishFarming. Newsweek, May 23. Academic OneFile. Available athttp://go.galegroup.com/ps/i.do?id=GALE%7CA371931688&v=2.1&u=auraria_main&it=r&p=AONE&sw=w&asid=6b5f606d549129586a0be3322ad0738a. Accessed on 17November 2015.
McMurtry, M., Sanders, D., Cure, J., Hodson, R., Haning, B., and St. Amand, P. 1997.Efficiency of water use of an integrated fish/vegetable co-culture system. Journal of theWorld Aquaculture Society 28. pp 420 – 428.
McMurtry, M.R., Sanders, D.C., Cure, J.D., Hodson, R.G., Haning, B.C., and St. Amand,E.C. 1997a. Efficiency of Water Use of an Integrated Fish/Vegetable Co-CultureSystem. Journal of the World Aquaculture Society 28 (4). pp 420–28
Nelson, C., Rosegrant, G., Mark, W., Jawoo, K., Richard, R., Timothy, S., Tingju, Z.,Claudia, R., et al. 2009a. Climate Change: Impact on Agriculture and Costs ofAdaptation. Intl Food Policy Res Inst.
Plawecki, R., Pirog, R., Montri, A., and Hamm, M. 2013. Comparative carbon footprintassessment of winter lettuce production in two climatic zones for Midwestern market.
63
Renewable agriculture and food systems 29 (4). pp 310-318.doi:10.1017/S1742170513000161.
Quinta R, Webb J, Thomas DN, Rigby M, Santos R (2013) Halophyte production inconstructed wetlands and hydroponic systems for aquaculture wastewater remediation.Aquaculture Conference 2013. Las Palmas, Gran Canaria.
Rabana, H.R. 1988. History of Aquaculture. ASEAN/UNDP/FAO Regional Small-ScaleCoastal Fisheries Development Project Manila, Philippines. Training Program for SeniorAquaculturists, SEAFDEC, Tigbauan, Iloilo, Philippines, 24 March 1988. Available athttp://academics.utep.edu/Portals/3341/GaBi%20Tutorial%20GEM%20class%202013_Finalized.pdf. Accessed on 30 November 2016.
Rakocy, J.E. & Lennard, W. 2012. Our Stories. The Aquaponic Doctors. Available athttp://theaquaponicsdoctors.com/our-story.php. Accessed on 10 March 2016.
Rakocy, J.E. 1998. Integrating hydroponic plant production with recirculating systemaquaculture: Some factors to consider. In: Proceedings of Second InternationalConference on Recirculating Aquaculture. pp 392–394.
Ramaswami, A., Janson, B., Hillman, T., Wendrowski, J., Reiner, M., and Posner, M.2007.Greenhouse Gas Inventory for the City & County of Denver. Available fromhttps://www.denvergov.org/Portals/771/documents/Climate/Denver%20GHG%20Inventory%20Report%20May15_formatted_final.pdf. Accessed 30 May 2016
Rifat, H., Ahmed, I. 2012. An Overview of Plant Growth Promoting Rhizobacteria (PGPR)for Sustainable Agriculture. Crop Production for Agricultural Improvement 557–79.doi:10.1007/978-94-007-4116-4_22.
Roque d’Orbcastel, E., Blancheton, and Aubin, J. 2009. Towards environmentally sustainableaquaculture: Comparison between two trout farming systems using life cycle assessment.Aquacultural Engineering. 40(3). pp 113-119.
Pimentel, D. et al. 2004. Water Resources: Agricultural and Environmental Issues.BioScience 54 (10): 909-918
Plawecki, R., Pirog, R., Montri, A., and Hamm, M. 2013. Comparative carbon footprintassessment of winter lettuce production in two climatic zones for Midwestern market.Renewable agriculture and food systems 29 (4). pp 310-318.doi:10.1017/S1742170513000161.
Skretting. 2014. Skretting Australia annual sustainability report. Available fromhttp://www.skretting.com/siteassets/au-temp-files/nexus-and-reports-andbrochures/2014-sustlocal-report-web.pdf. Accessed on 10 July 2016.
Somerville C., Cohen M., Pantanella E., Stankus A., & Lovatelli A. 2014, Small-scaleaquaponics food production: Integrated fish and plant farming. FAO Fisheries andAquaculture Technical Paper No. 589, Rome, FAO. 82 pp. Available fromhttp://www.fao.org/3/a-i4021e/index.html Accessed on 17 November 2015.
64
Stanford University. 2009. Half Of Fish Consumed Globally Is Now Raised On Farms, StudyFinds. ScienceDaily. 8 September 2009. Available atwww.sciencedaily.com/releases/2009/09/090907162320.htm. Accessed on 30 November2016.
Storey, A. 2016. Flushing Hydroponic Systems: Nutrient Imbalance, waste and an alternativesolution. Bright Agrotech, LLC. Available at http://blog.brightagrotech.com/flushing-hydroponic-systems-nutrient-imbalance-waste-and-an-alternative-solution. Accessed11/30/2016
Svoboda, S. 1995. Note on Life Cycle Analysis. Pollution Prevention in Corporate Strategy.National pollution prevention center for higher education. University of Michigan.Available athttp://www.umich.edu/~nppcpub/resources/compendia/CORPpdfs/CORPlca.pdf.Accessed on 15 November 2016.
The Futurist. 2012. An Aquaponic Recycling System in Every Kitchen? AcademicOneFile. Available athttp://go.galegroup.com/ps/i.do?id=GALE%7CA306242610&v=2.1&u=auraria_main&it=r&p=AONE&sw=w&asid=f9a1d2d88355bebe767c176f337975db. Accessed on 13March 2016.
The Futurist. 2011. Aquariums as Farms. Academic OneFile. Available athttp://go.galegroup.com/ps/i.do?id=GALE%7CA270896433&v=2.1&u=auraria_main&it=r&p=AONE&sw=w&asid=5abdd661d4d4d2952d221983988b69ea. Accessed on 13March 2016.
Todd, J.A., Curran, M.A., 1999. Streamlined Life-Cycle Assessment: a Final Report from theSETAC North America Streamlined LCA Workgroup. Society of EnvironmentalToxicology and Chemistry and SETAC Foundation for Environmental Education,Pensacola, FL. pp 32501-3370. Available at ftp://cee.ce.cmu.edu/HSM/Public/WWW/lca-readings/streamlined-lca.pdf. Accessed on 15 November 2016.
Twells, L.K., and Newhook, L.A. 2011. Obesity Prevalence Estimates in a CanadianRegional Population of Preschool Children Using Variant Growth References. BMCPediatrics 11 (1): pp 21. doi:10.1186/1471-2431-11-21.
United Nations. 2015. World Population Prospects: The 2015 Revision, Key Findings andAdvance Tables. Working Paper No. ESA/P/WP.241. United Nations, Department ofEconomic and Social Affairs, Population Division. Available athttps://esa.un.org/unpd/wpp/publications/files/key_findings_wpp_2015.pdf. Accessed on30 November 2016.
United States Census. 2015. U.S. and World Population Clock. United States Census Bureau.October 20th, 2015. Available at http://www.census.gov/popclock/. Accessed on 17November 2015.
65
United States Department of Agriculture. 2014. Fish, tilapia, cooked, dry heat nutrition factscalories. Self Nutrition Data. Available at http://nutritiondata.self.com/facts/finfish-and-shellfish-products/9244/2. Accessed on 15 November 2016.
United States Department of Agriculture. 2016. Organic Labeling USDA AgriculturalMarketing Service. Available at https://www.ams.usda.gov/rules-regulations/organic/labeling. Accessed on 30 November 2016.
United States National Library of Medicine. 2013. TOXMAP Toxic Release Inventory andSuperFund Programs. National Institute of Health. Available at http://toxmap-classic.nlm.nih.gov/toxmap/combo/triIdentify.do. Accessed on 17 November 2015.
Vitousek, P.M. et al. 2009. Nutrient Imbalances in Agricultural Development. Science 324:1519 – 1520.
Wei, Y., Huang, C., Patrick, T., Lam, I., and Yuan, Z. 2015. Sustainable UrbanDevelopment: A Review on Urban Carrying Capacity Assessment. HabitatInternational 46 (April). pp 64–71. doi:10.1016/j.habitatint.2014.10.015.
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APPENDIX A
Flourish Farm’s Delivery Locations
1. The Growhaus – 4751 York Street, Denver CO 80216
2. Blue Moon Brewing Company – 3750 Chestnut Place, Denver CO 80216
3. Comida at the Source – 3350 Brighton Boulevard #105, Denver CO 80216
4. Mondo Market – 3350 Brighton Boulevard #115, Denver CO 80216
5. The Populist – 3163 Larimer Street, Denver CO 80205
6. The Preservery – 3040 Blake Street #101, Denver CO 80205
7. Nocturne – 1330 27th Street, Denver CO 80205
8. Aloy Thai – 2134 Larimer St., Denver CO 80205
9. Vesta Dipping Grill – 1822 Black Street, Denver CO 80202
10. Cholon Modern Asian Bistro- 1555 Blake Street #101, Denver CO 80202
11. Squeaky Bean- 1500 Wynkoop Street #101, Devner CO 80202
12. Central Bistro – 1691 Central Street, Denver CO 80211
13. Western Daughters Butcher Shoppe – 3326 Tejon Street, Denver CO 80211
14. Linger – 2030 West 30th Avenue, Denver CO 80211
15. St. Kilian’s Cheese Shop – 3211 Lowell Blvd, Denver CO 80211
16. Charcoal Restaurant – 43 West 9th Avenue, Denver CO 80204
17. Marczyk’s Fine Foods (17th) – 770 East 17th Avenue, Denver CO 80203
18. Thump Coffee – 1201 East 13th Avenue, Denver CO 80218
19. SAME Café – 2023 East Colfax Avenue, Denver CO 80218
20. Denver Zoo – 300 Steele St., Denver CO 80205
21. Marczyk’s Fine Foods (Colfax) – 5100 East Colfax Avenue, Denver CO 80220
22. The Plimoth – 2335 East 28th Avenue, Denver CO 80205
23. GrowHaus - 4751 York Street, Denver CO 80216
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APPENDIX B
Flourish Farm’s Produce Production 2014
Values
Row Labels
Sum ofUnitsharvested
Sum ofHarvestedweight (oz)
Average ofAverageweight/unit (oz)
Baby Greens mix 166 367 2.58Basil Genovese 48 104 2.17Bok choy tatsoi 1148 2433.12 2.631034483Bright LightsRainbow SwissChard 93 365.25 1.67Celery Utah 55 80 1.45Chinese cabbageMichihili 52 189 3.77Cilantro Calypso 327 633.2 2.145833333Collard Greens 23 84 3.65Collards Vates 250 447.25 2.02125Common mint 103 260 3.14Dwarf blue curledkale 142 370.25 3.266Endive Salad King 51 122.45 2.4Flat-leaf parsley 22 143Grand Rapids lettuceGreen Star 2549 9393.69 3.373069307Green Bibb Lettuce 3 12 4Green bibb lettuceButtercrunch 522 1057.75 2.484615385Green Bibb LettuceFlandria 679 2549.19 3.789Green bibb lettuceRex 5129 16612.90167 3.439322034Green butterheadlettuce 133 561 3.428Green romaineClaremont 364 1395.9 3.574285714Green romaine GreenForest 26 179 6.88Green romaineRidgeline 16 86 5.38Helvius romaine 24 126 5.25Hybrid kale 105 298.75 2.9425Kale Starbor 1514 3455.5 2.812826087Mache corn salad 27 92 3.41Mustard Greens 194.5 336 2.97
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New Red FireParris Island romaine 8089 27568.71 3.433843416Purple mizuna 473 1490.8 3.541764706Purslane Red Gruner 42 86.6 2.19Red Bibb LettuceCherokee 40 209.5Red bibb lettuce RedCross 46 171 3.925Red bibb lettuceSkyphos 76 312 4.156666667Red butterheadlettuce 16 64 4Red Giant mustard 252 1121.875 4.0375Red leaf lettuce LolloRossaRed LettuceCherokee 23 132.75Red oakleaf lettuceMalawi 97 309 3.245Red oakleaf lettuceOscarde 669 1567.885 2.212Red romaine GarnetRose 28 96 3.43Red romaineOutredgeous 73 251 3.5825Red romaine Rouged'Hiver 26 105.5 4.06Red Russian kale 2564 6838.665 2.891392405Red Summer Crisplettuce Cherokee 849 2519.24 2.985151515Red velvet lettuce 42 144 3.145Redbor kale 7 14.5 2.07Red-veined sorrel 203 402.5 2.504285714Ridgeline Romaine 48 207.75 4.63Romaine Coastal Star 80 352 4.383333333Romaine lettuceFreckles 24 94 3.92Romaine Red Rosie 20 24 1.2Romaine Ridgeline 130 758.1 3.345Romaine Sparx 175 769.24 2.39Swiss chard BrightLights rainbow 1756 5139.6 3.355769231OrangeSwiss chard white 56 286 5.105Tuscan kale 828 2289.25 3.033214286Watercress 56 144 2.57
Grand Total 30553.5 95223.66667 3.240651751
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APPENDIX C
Flourish Farm’s Integrated Pest Management Use 2014
Row LabelsSum of Preparation
(mL/L)
Aqua-C 4750Azamax 32Azatrol 214biomin Ca 6Botanigaurd 91.5Bti 2392M-pede 294Serenade 756
Grand Total 8535.5