AERMOD

The AERMOD atmospheric dispersion modeling system is an integrated system that includes three modules:^[1]^[2]^[3]

A steady-state dispersion model designed for short-range (up to 50 kilometers) dispersion of direct air pollutant emissions primarily from stationary industrial sources.
A meteorological data preprocessor (AERMET) that accepts surface meteorological data, upper air soundings, and optionally, data from on-site instrument towers. It then calculates atmospheric parameters needed by the dispersion model, such as atmospheric turbulence characteristics, mixing heights, friction velocity, Monin-Obukov length and surface heat flux.
A terrain preprocessor (AERMAP) whose main purpose is to provide a physical relationship between terrain features and the behavior of air pollution plumes. It generates location and height data for each receptor location. It also provides information that allows the dispersion model to simulate the effects of air flowing over hills or splitting to flow around hills.

AERMOD also includes PRIME (Plume Rise Model Enhancements) ^[4] which is an algorithm for modeling the effects of downwash created by the pollution plume flowing over nearby buildings.

YouTube Encyclopedic

1/3
Views:
2 626
10 101
4 084

Transcription

History of the development of AERMOD

AERMOD was developed by the AERMIC (American Meteorological Society (AMS)/United States Environmental Protection Agency (EPA) Regulatory Model Improvement Committee), a collaborative working group of scientists from the AMS and the EPA.^[1] The AERMIC was initially formed in 1991.

The AERMIC developed AERMOD in seven steps:

Initial model formulation
Developmental evaluation
Internal peer review and beta testing
Revised model formulation
Performance evaluation and sensitivity testing
External peer review
Submission to the EPA for consideration as a regulatory model.

On April 21 of 2000, the EPA proposed that AERMOD be adopted as the EPA's preferred regulatory model for both simple and complex terrain.^[5] On November 9 of 2005, AERMOD was adopted by the EPA and promulgated as their preferred regulatory model, effective as of December 9 of 2005.^[6] The entire developmental and adoption process took 14 years (from 1991 to 2005).

Features and capabilities of AERMOD

Some of the primary features and capabilities of AERMOD are:^[2]^[7]^[8]

Source types: Multiple point, area and volume sources
Source releases: Surface, near surface and elevated sources
Source locations: Urban or rural locations. Urban effects are scaled by population.
Plume types: Continuous, buoyant plumes
Plume deposition: Dry or wet deposition of particulates and/or gases
Plume dispersion treatment: Gaussian model treatment in horizontal and in vertical for stable atmospheres. Non-Gaussian treatment in vertical for unstable atmospheres
Terrain types: Simple or complex terrain
Building effects: Handled by PRIME downwash algorithms
Meteorology data height levels: Accepts meteorology data from multiple heights
Meteorological data profiles: Vertical profiles of wind, turbulence and temperature are created

References

^ ^a ^b AERMOD:Description of Model Formulation
^ ^a ^b Prater, E.T. and Midgley, C., A new air dispersion modeling system is helping create more accurate industrial source models, Environmental Protection, Vol. 17, No. 3, Stevens Publishing
^ Brode, R.W., AERMOD Technical Forum, EPA R/S/L Modelers Workshop, San Diego, California, April 16, 2006
^ Development and Evaluation of the PRIME Plume Rise and Building Downwash Model
^ Federal Register: April 21, 2000 (Volume 65, Number 78) Proposed Rule
^ Federal Register: November 9, 2006 (Volume 70, Number 216) Archived November 5, 2006, at the Wayback Machine Final Rule
^ AERMOD:Latest Features and Evaluation Results (EPA-454/R-03-003)
^ McVehil-Monnet Associates Air Quality Newsletter

External links

The EPA's download site for AERMOD (Model code, User's Guide and other material)
Brode, R.W., Implementation and Evaluation of the AERMOD-PRIME Model (AMS Conference, May 21, 2002)

Atmospheric, oceanographic, cryospheric, and climate models

Model types
Atmospheric model Oceanographic model Cryospheric model Climate model Numerical weather prediction Tropical cyclone forecast model Atmospheric dispersion modeling Chemical transport model Upper-atmospheric models Ensemble forecasting Model output statistics Meteorological reanalysis Parametrization

Specific models

Climate	IGCM HadCM3 HadGEM1 GFDL CM2.X CGCM CCSM CESM CFSv2 ECHAM
Global weather	IFS (ECMWF) FIM GEM / GDPS GFS MPAS NAEFS NAVGEM UM JMA-GSM GME / ICON ARPEGE
Regional and mesoscale atmospheric	NAM RR / RAP RAMS WRF RAQMS HIRLAM LAPS RPM HWRF RGEM HRDPS
Regional and mesoscale oceanographic	HyCOM ROMS POM MOM FVCOM MITgcm FESOM ADCIRC
Atmospheric dispersion	ADMS AERMOD ATSTEP AUSTAL2000 CALPUFF DISPERSION21 ISC3 MEMO MERCURE NAME OSPM PUFF-PLUME RIMPUFF SAFE AIR SILAM
Chemical transport	CLaMS MOZART GEOS-Chem CHIMERE
Land surface parametrization	JULES CLASS ISBA
Cryospheric models	CICE
Discontinued	Eta LFM MM5 NGM NOGAPS RUC

This page was last edited on 4 March 2022, at 23:46

From Wikipedia, the free encyclopedia