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Investigating processes influencing simulation of local Arctic wintertime anthropogenic pollution in Fairbanks, Alaska during ALPACA-2022.

Authors :
Brett, Natalie
Law, Kathy S.
Arnold, Steve R.
Fochesatto, Javier G.
Raut, Jean-Christophe
Tatsuo Onishi
Gilliam, Robert
Fahey, Kathleen
Huff, Deanna
Pouliot, George
Barret, Brice
Dieudonné, Elsa
Pohorsky, Roman
Schmale, Julia
Baccarini, Andrea
Bekki, Slimane
Pappaccogli, Gianluca
Scoto, Federico
Decesari, Stefano
Donateo, Antonio
Source :
Atmospheric Chemistry & Physics Discussions; 6/4/2024, p1-55, 55p
Publication Year :
2024

Abstract

Lagrangian tracer simulations are deployed to investigate processes influencing vertical and horizontal dispersion of anthropogenic pollution in Fairbanks, Alaska, during the ALPACA-2022 field campaign. Simulations of carbon monoxide (CO), sulphur dioxide (SO<subscript>2</subscript>) and nitrogen oxides (NO<subscript>x)</subscript>, including surface and elevated emissions, are highest at the surface under very cold stable conditions. Regional enhancements, simulated up to 200 m, are due to elevated power plant emissions above 50 m, with south-westerly pollutant outflow. Fairbanks regional pollution may be contributing to wintertime Arctic haze. Inclusion of a novel power plant plume rise treatment that considers the presence of surface and elevated temperature inversion layers leads to improved agreement with observed CO and NO<subscript>x</subscript> plumes with discrepancies attributed to, for example, displacement of plumes by modelled winds. At the surface, model results show that observed CO variability is largely driven by meteorology and to a lesser extent by emissions, although simulated tracers are sensitive to modelled vertical dispersion. Modelled underestimation of surface NO<subscript>x</subscript> during very cold polluted conditions is considerably improved following the inclusion of substantial increases in diesel vehicle NO<subscript>x </subscript>emissions at cold temperatures (e.g. a factor of 6 at -30 °C). In contrast, overestimation of surface SO<subscript>2</subscript> is attributed to issues related to the vertical dispersion of elevated space heating emissions during strongly and weakly stable conditions. This study highlights the need for improvements to local wintertime Arctic anthropogenic surface and elevated emissions and improved simulation of Arctic stable boundary layers. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
16807367
Database :
Complementary Index
Journal :
Atmospheric Chemistry & Physics Discussions
Publication Type :
Academic Journal
Accession number :
177787479
Full Text :
https://doi.org/10.5194/egusphere-2024-1450