Algorithms and analytical solutions for rapidly approximating long-term dispersion from line and area sources

Predicting long-term mean pollutant concentrations in the vicinity of airports, roads and other industrial sources are frequently of concern in regulatory and public health contexts. Many emissions are represented geometrically as ground-level line or area sources. Well developed modelling tools such as AERMOD and ADMS are able to model dispersion from finite (i.e. non-point) sources with considerable accuracy, drawing upon an up-to-date understanding of boundary layer behaviour. Due to mathematical difficulties associated with line and area sources, computationally expensive numerical integration schemes have been developed. For example, some models decompose area sources into a large number of line sources orthogonal to the mean wind direction, for which an analytical (Gaussian) solution exists. Models also employ a time-series approach, which involves computing mean pollutant concentrations for every hour over one or more years of meteorological data. This can give rise to computer runtimes of several days for assessment of a site. While this may be acceptable for assessment of a single industrial complex, airport, etc., this level of computational cost precludes national or international policy assessments at the level of detail available with dispersion modelling. In this paper, we extend previous work [S.R.H. Barrett, R.E. Britter, 2008. Development of algorithms and approximations for rapid operational air quality modelling. Atmospheric Environment 42 (2008) 8105–8111] to line and area sources. We introduce approximations which allow for the development of new analytical solutions for long-term mean dispersion from line and area sources, based on hypergeometric functions. We describe how these solutions can be parameterized from a single point source run from an existing advanced dispersion model, thereby accounting for all processes modelled in the more costly algorithms. The parameterization method combined with the analytical solutions for long-term mean dispersion are shown to produce results several orders of magnitude more efficiently with a loss of accuracy small compared to the absolute accuracy of advanced dispersion models near sources. The method can be readily incorporated into existing dispersion models, and may allow for additional computation time to be expended on modelling dispersion processes more accurately in future, rather than on accounting for source geometry.

[1]  P. A. Sheppard,et al.  Atmospheric Diffusion , 1962, Nature.

[2]  S. Hameed,et al.  Steady-state solution of the semi-empirical diffusion equation for area sources , 1975 .

[3]  Marcus Hirtl,et al.  Evaluation of two dispersion models (ADMS-Roads and LASAT) applied to street canyons in Stockholm, London and Berlin , 2007 .

[4]  Louis J. Thibodeaux,et al.  Modeling Short Range Air Dispersion from Area Sources of Non-buoyant Toxics , 1990 .

[5]  Steven R. Hanna,et al.  Evaluation of the ADMS, AERMOD, and ISC3 dispersion models with the OPTEX, Duke Forest, Kincaid, Indianapolis and Lovett field datasets , 2001 .

[6]  Rashmi S. Patil,et al.  A GENERAL FINITE LINE SOURCE MODEL FOR VEHICULAR POLLUTION PREDICTION , 1989 .

[7]  Akula Venkatram,et al.  Aermod: Description of model formulation , 2000 .

[8]  Kenneth L. Calder Multiple-source plume models of urban air pollution—their general structure , 1977 .

[9]  Mukesh Khare,et al.  Line source emission modelling , 2002 .

[10]  Irene A. Stegun,et al.  Handbook of Mathematical Functions. , 1966 .

[11]  D O Marin,et al.  An urban diffusion model for estimating long term average values of air quality. , 1971, Journal of the Air Pollution Control Association.

[12]  David P. Chock On estimating air pollution concentrations from a highway in an oblique wind , 1974 .

[13]  F. B. Smith,et al.  UK-ADMS: A new approach to modelling dispersion in the earth's atmospheric boundary layer , 1994 .

[14]  Rex Britter,et al.  Modelling environmental & economic impacts of aviation: Introducing the aviation integrated modelling project , 2007 .

[15]  Gianni Tinarelli,et al.  Simulations of atmospheric dispersion in an urban stable boundary layer , 2001 .

[16]  Akula Venkatram,et al.  AERMOD: A dispersion model for industrial source applications. Part II: Model performance against 17 field study databases , 2005 .

[17]  Rex Britter,et al.  Development of algorithms and approximations for rapid operational air quality modelling , 2008 .

[18]  D. J. Hall,et al.  Validation of ADMS against wind tunnel data of dispersion from chemical warehouse fires , 1999 .

[19]  Jian-Ming Jin,et al.  Computation of special functions , 1996 .

[20]  H. Higson COMPARISON OF MODEL EVALUATION METHODOLOGIES WITH APPLICATION TO ADMS 3 AND US MODELS , 1999 .

[21]  Rex Britter,et al.  Short-range vertical dispersion from a ground level source in a turbulent boundary layer , 2003 .

[22]  T. W. Horst,et al.  Approximating dispersion from a finite line source , 2006 .

[23]  Gordon J. Esplin,et al.  Approximate explicit solution to the general line source problem , 1995 .