Concentration Trajectory Route of Air pollution with an Integrated Lagrangian model (C-TRAIL Model v1.0) derived from the Community Multiscale Air Quality Model (CMAQ Model v5.2)
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Published:2020-08-05
Issue:8
Volume:13
Page:3489-3505
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ISSN:1991-9603
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Container-title:Geoscientific Model Development
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language:en
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Short-container-title:Geosci. Model Dev.
Author:
Pouyaei Arman,Choi Yunsoo,Jung Jia,Sadeghi Bavand,Song Chul Han
Abstract
Abstract. This paper introduces a novel Lagrangian model
(Concentration Trajectory Route of Air pollution with an Integrated
Lagrangian model, C-TRAIL version 1.0) output from a Eulerian air quality
model for validating the source–receptor direct link by following polluted
air masses. To investigate the concentrations and trajectories of air masses
simultaneously, we implement the trajectory-grid (TG) Lagrangian advection
scheme in the CMAQ (Community Multiscale Air Quality) Eulerian model version
5.2. The TG algorithm follows the concentrations of representative air
“packets” of species along trajectories determined by the wind field. The
diagnostic output from C-TRAIL accurately identifies the origins of
pollutants. For validation, we analyze the results of C-TRAIL during the
KORUS-AQ campaign over South Korea. Initially, we implement C-TRAIL in a
simulation of CO concentrations with an emphasis on the long- and
short-range transport effects. The output from C-TRAIL reveals that local
trajectories were responsible for CO concentrations over Seoul during the
stagnant period (17–22 May 2016) and during the extreme pollution period
(25–28 May 2016), highly polluted air masses from China were distinguished
as sources of CO transported to the Seoul Metropolitan Area (SMA). We
conclude that during the study period, long-range transport played a crucial
role in high CO concentrations over the receptor area. Furthermore, for May 2016, we find that the potential sources of CO over the SMA were the result
of either local transport or long-range transport from the Shandong
Peninsula and, in some cases, from regions north of the SMA. By identifying
the trajectories of CO concentrations, one can use the results from C-TRAIL
to directly link strong potential sources of pollutants to a receptor in
specific regions during various time frames.
Publisher
Copernicus GmbH
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