Abstract
Abstract. Plumes from the boreal spring biomass burning (BB) in northern peninsular Southeast Asia (nPSEA) are lifted into the subtropical jet stream and transported and deposited across nPSEA, South China, Taiwan and even the western North Pacific Ocean. This paper as part of the Seven SouthEast Asian Studies (7-SEAS) project effort attempts to improve the chemical weather prediction capability of the Weather Research and Forecasting coupled with the Community Multiscale for Air Quality (WRF–CMAQ) model over a vast region, from the mountainous near-source burning sites at nPSEA to its downwind region. Several sensitivity analyses of plume rise are compared in the paper, and it is discovered that the initial vertical allocation profile of BB plumes and the plume rise module (PLMRIM) are the main reasons causing the inaccuracies of the WRF–CMAQ simulations. The smoldering emission from the Western Regional Air Partnership (WRAP) empirical algorithm included has improved the accuracies of PM10, O3 and CO at the source. The best performance at the downwind sites is achieved with the inline PLMRIM, which accounts for the atmospheric stratification at the mountainous source region with the FINN burning emission dataset. Such a setup greatly improves not only the BB aerosol concentration prediction over near-source and receptor ground-based measurement sites but also the aerosol vertical distribution and column aerosol optical depth of the BB aerosol along the transport route. The BB aerosols from nPSEA are carried by the subtropical westerlies in the free troposphere to the western North Pacific, while BB aerosol has been found to interact with the local pollutants in the Taiwan region through three conditions: (a) overpassing western Taiwan and entering the central mountain area, (b) mixing down to western Taiwan, (c) transport of local pollutants upwards and mixing with a BB plume on higher ground. The second condition, which involves the prevailing high-pressure system from Asian cold surge, is able to impact most of the population in Taiwan.
Highlights
Large quantities of gaseous and aerosol pollutants released from biomass burning affect regional air quality, radiative forcing, public health and economic burden, especially in Southeast Asia (Chen et al, 2017; Lee et al, 2017; Pani et al, 2018, 2020)
With moderate burning occurring in northern peninsular Southeast Asia (nPSEA), this El Niño– Southern Oscillation (ENSO)-neutral year is chosen because the Lulin Atmospheric Background Station (LABS) mainly received the biomass burning (BB) plumes with minimal influence from the Asian dust storm to Taiwan (NOAA-ESRL, 2020; TAQM, updated daily; Kong et al 2021)
In line with the 2013 7-SEAS spring campaign conducted in nPSEA, the Micro-Pulse Lidar Network (MPLNET) device is located at the Doi Ang Khang (DAK) meteorology station to collect the near-source aerosol vertical distribution profile (L1.5a) data
Summary
Large quantities of gaseous and aerosol pollutants released from biomass burning affect regional air quality, radiative forcing, public health and economic burden, especially in Southeast Asia (Chen et al, 2017; Lee et al, 2017; Pani et al, 2018, 2020). The modeled columnar aerosol optical depth (AOD) is found to be comparable with aerosol products of the Aerosol Robotic Network (AERONET) and the Moderate Resolution Imaging Spectroradiometer (MODIS) sensor as well as columnar CO and NO2 at the burning source over the nPSEA region, but great discrepancies are found for the spatial distribution of downwind plumes (Dong and Fu, 2015b; Fu et al, 2012). In those models, the vertical distribution percentage of BB emission was set to be constant throughout the case.
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