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1. Development of an urban CFD flow model called UrbanSTREAM to predict mean flow and turbulence at urban micro-scale
2. Urban parameterization for meso-γ scale numerical weather prediction model called UrbanGEM-LAM
3. Coupling urban micro-scale model with urbanized meso-γ –scale numerical weather prediction model
4. Development of a Lagrangian stochastic model called UrbanLS for prediction of urban dispersion
5. Validation of the fully coupled modeling prototype6. Development a methodology for source (event) reconstruction
CRTI 02-0093RD: Advanced Emergency Response CRTI 02-0093RD: Advanced Emergency Response System for CBRN Hazard Prediction and Assessment for System for CBRN Hazard Prediction and Assessment for
the Urban Environmentthe Urban Environment
Project Lead Organization:Project Lead Organization: Environment Canada. Contact: Richard Hogue, Environment Canada. Contact: Richard Hogue, Environmental Emergency Response DivisionEnvironmental Emergency Response Division, Canadian Meteorological Centre, Canadian Meteorological CentreFederal Partners:Federal Partners: Defense R&D Canada - Suffield, Health Canada Radiation Protection Bureau, Atomic Energy Canada Limited Defense R&D Canada - Suffield, Health Canada Radiation Protection Bureau, Atomic Energy Canada LimitedIndustry Partners:Industry Partners: J.D. Wilson and Associates (U. of Edmonton), Waterloo CFD Engineering Consulting Inc. (U. Of Waterloo) J.D. Wilson and Associates (U. of Edmonton), Waterloo CFD Engineering Consulting Inc. (U. Of Waterloo)
Given an actual release of hazardous material into the atmosphere, emergency response is a problem that requires a delicate balance between accuracy and timeliness.
Dispersion modeling in urban zones requires the resolution of all the significant local terrain features as well as the details of the ambient meteorology, horizontal and vertical.
Although there are commercial off-the-shelf modeling products that claim to address this problem, most of these products use simple Gaussian plume dispersion models that are designed for flat and unobstructed surfaces, and merely superimpose the hazardous plume predictions on the urban terrain, without accounting for influences of buildings. This can result in large errors in the dispersion predictions. Furthermore, these approaches do not have access to 3D meteorological models as input, which is an integral part of this project.
A framework that provides detailed real time modeling forecasts is important to make relevant decisions to save lives or prevent injury and to minimize contamination and health consequences. This framework can also be used in planning/risk assessment and post-event/forensic applications.
The objective of this project is to develop and validate a prototype state-of-the-science multi-scale modeling system for prediction of the transport and dispersion of CBRN materials in the urban environment and beyond.
CRTI symposium 2007
Objective
Six main components of the project
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Concept
Prototype
Mesoscale
Urban scale
Building scale
Mesoscale
Urban scale
Building scale
Source Type
Defines Flow Defines Dispersion
Chemical agent
Biological agent
Fluid Dynamics Models Plume Dispersion Models
BCs
BCs
Operational ModelGEM 15km
“Urbanized” GEM/LAMCascade 2.5km – 1km- 250m
urbanSTREAM CFD model
MLPD
urbanLSurbanEU
UrbanLSdispersion
model
• CBRN releases induces impacts over many spatial scales
• Need multi-scale approach where flow and dispersion are performed within “nested” domains
Radiological agent
• Meso- and off-line• Regional NWP
MODELING DATABASES TRANSFERSMEASUREMENTS
and OBSERVATIONS
• TEB• 3D-turbulence• Boundary conditions
• Surface fields• Anthropogenic heat sources
UrbanSTREAMUrbanGEM/LAMUrbanLSUrbanEU
VisualizationProduct generation
urbanBLSurbanAEU
Bayesian inference for inverse source determination
3D buildings data
• MUSE-1 (2005)• MUSE-2 (2006)
CRTI symposium 2007
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Prototype implementation
A full prototype of the modeling system has been implemented in the computing environment of a government operations centre at the Canadian Meteorological Centre’s (CMC) Environmental Emergency Response Division (EERD).
Application in test mode of hypothetical release to Vancouver and Montreal
Wind vectors
3D streamlines
Isosurface of concentration level of material
GEM-LAM - Vancouver cascade configuration2.5km 1km 250m
Vancouver - urban classification
Vertical cross-sectionof concentration
Prototype also running over Montreal
Accumulated concentrationat ground level
CRTI symposium 2007
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Validation Joint Urban 2003: Atmospheric flow and dispersion study held in Oklahoma City in July 2003. 10 Intensive Observing Periods (IOPs): 6 day’s IOPs and 4 night’s IOPs.
Measured and Predicted Concentration
83 84 860
500
1000
1500
2000
2500
3000
Detector ID
Mea
n Con
cent
ration
(pptv
)
5th Street
SourceSource
ExperimentalurbanEUurbanAEUurbanLS
72 73 74 760
500
1000
1500
2000
2500
3000
3500
Detector ID
Mea
n Con
cent
ration
(pptv
)
4th Street
Montreal Urban Snow Experiment (MUSE)Montreal Urban Snow Experiment (MUSE)
▪▪ Field campaign to document the evolution of surface Field campaign to document the evolution of surface characteristics and energy budgets in a dense urban area characteristics and energy budgets in a dense urban area during the winter-spring transition. The results are used to during the winter-spring transition. The results are used to validate the meso-scale model’s validate the meso-scale model’s urban surface schemeurban surface scheme in in such conditions.such conditions.▪ MUSE-2005 (February-March 2005), MUSE 2006 MUSE-2005 (February-March 2005), MUSE 2006 (January-March 2006)(January-March 2006)▪ 4 IOPs
Δθ
Urban effects at night:Figure 1: θ = Potential Temperature at 50m AGL and at time 0600 LSTFigure 2: Δθ = θ(Urban)–θ(Rural) at 50m AGL and at time 0600 LSTFigure 3: ▪ Vertical extension of the UHI in the first 200 m ▪ Decrease of the vertical extension during the night
Figure 1 Figure 2 Figure 3
UrbanGEM validation: Oklahoma City, IOP9 From JU03, Illustration of the Urban Heat Island
Fig. 1: 12 rural Stations (MESONET) Fig. 2: 13 urban Stations (PWIDS) Fig. 3: Canopy level UHI positive at night, negative at day
Fig. 1 Fig. 2
Fig. 3
Turbulent Fluxes: ▬ Qh and ▬ Qe
Wind at 2m AGLUrbanStream
Isopleths of concentration field, UrbanLS model
CRTI symposium 2007
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Inverse Source Determination and Bayesian Inference (component 6): Application to Oklahoma City using 4 detectors
Actual source location:
(xs , zs) = (3.2506,1.5537)
74
Detector
Source
Distributed drag force representation
Application examples:
• Localization of leakage of toxic gases and other pollutants (regulatory application)
• Terrorist incidents – localization of unknown source following event detection by network of CBRN sensors (“electronic noses”) as quickly as possible
• Comprehensive Nuclear Test Ban Treaty (CTBT) “sniffing” out clandestine nuclear tests (133Xe - Xenon) network
Recent Results
N
CRTI symposium 2007
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Finalize work on inverse source determination and validation over OKC Finalize documentation of all aspects of the project Finalize technical aspects of prototype installation over Montreal and Vancouver (validation of UrbanGEM-LAM cascade (bi-monthly basis) and test dispersion scenarios) Examine the possibility of using the validation datasets from the New-York tracer experiment
Submitted a follow-up proposal project: CRTI-06-0198TD: "Towards an Operational Urban Modeling System for CBRN Emergency Response and Preparedness"; Aims the implementation of the prototype to 9 major Canadian cities in a technology demonstration context as well as improvements to the prototype components and further validation. Important aspect is a better linkage with the user community and focus on preparation for Vancouver 2010 Olympics.
CRTI projects:
• Application of prototype to provide simulation scenarios to project CRTI 05-0058TD - “Unified Interoperability Solution set to Support CONOPS Framework Development -- Municipal-Provincial-Federal Collaboration to CBRN Response”
• Application as input to ARGOS system under CRTI 01-0080TA “Information Management and Decision Support System for Radiological-Nuclear (RN) Hazard Preparedness & Response”• Application to consider precipitation scavenging under CRTI 02-0041RD “Real Time Determination of Area of Influence of CBRN Releases”• Application to high resolution situations of dispersion around infected barns and biological releases under CRTI 02-0066RD “Development of simulation programs to prepare against and manage outbreaks of highly contagious diseases of animals”• Links with dispersion assessment under CRTI 03-0018RD “Experimental Characterization of Risk for Radiological Dispersal Devices (RDDs)”• Links with dispersion assessment under CRTI 05-0014RTD “Experimental and Theoretical Development of a Re-suspension Database to Assist Decision Makers during a RDD Event”
EPiCC (Environmental Prediction in Canadian Cities), a project under CFCAS (The Canadian Foundation for Climate and Atmospheric Sciences) which aims to better understand meteorological processes in Canadian cities. Emphasis and detailed observational field studies are being implemented over Vancouver and Montreal.
Links to other projects
Next steps Project now 90% complete, ends March 2008
CRTI symposium 2007
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