Reprint

High Performance Computing Serving Atmospheric Transport & Dispersion Modelling

Edited by
February 2023
304 pages
  • ISBN978-3-0365-6581-1 (Hardback)
  • ISBN978-3-0365-6580-4 (PDF)

This is a Reprint of the Special Issue High Performance Computing Serving Atmospheric Transport & Dispersion Modelling that was published in

Chemistry & Materials Science
Environmental & Earth Sciences
Summary

This reprint brings together fifteen articles published in the Special Issue of the journal Atmosphere, entitled “High-Performance Computing Serving Atmospheric Transport & Dispersion Modelling”. These articles cover a wide variety of topics related to air quality in urban areas and nature-based solutions to improve it in the context of climate change; impact studies on human health and the environment of facilities and infrastructure projects as well as risk studies; the assessment of emerging threats; and preparations for and responses to emergencies involving toxic, flammable, or explosive atmospheric releases. As the fifteen articles presented here remarkably illustrate, what these contemporary topics have in common is the implementation of multi-scale simulations of atmospheric transport and dispersion by means of physical models of computational fluid dynamics (CFDs), whose potential is enhanced by high-performance computing (HPC). This reprint thus addresses the answers provided by modelling and the most advanced simulations to some societal matters of major interest.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
operational emergency modeling; atmospheric release; high-resolution metric grid; 3D; PMSS modeling system; Code_Saturne; EMERGENCIES project; lattice Boltzmann method; large eddy simulation; pollutant dispersion; urban physics; urban air pollution; nature-based solutions; green infrastructure; PMSS Lagrangian model; NOx; PM10; large-eddy simulation; plume dispersion; urban area; coupling simulation; mesoscale meteorological simulation model; meteorological observation; large eddy simulation; graphics processing unit computing; atmospheric dispersion modelling; microscale dispersion; model validation; large-eddy simulation; database; on-site meteorological observation; water mist dispersion; lagrangian dispersion model; operational emergency modeling; atmospheric release; high-resolution metric grid; web visualization; web mapping; emergencies project; atmospheric boundary layer; OpenFOAM; gas dispersion; CFD; turbulence model; hazard assessment; horizontal homogeneity; wind field; deposition; machine learning; hazardous release; WRF; FLEXPART; prediction; air pollution; air quality modelling; ADMS-Urban; high performance computing; HPC; West Midlands; air quality; urban scale; traffic emissions; micro-scale dispersion models; HPC; aerosols; South Asia; WRF-Chem; precipitation; CAPE; CIN; urban dispersion; large eddy simulation; complex terrain; fast-response dispersion modeling; computational fluid dynamics; RANS; urban dispersion modelling; Reynolds-averaged Navier–Stokes; situational awareness; CityGML; air quality impact study; 3D; PMSS model; high resolution grid

Related Books