Important Fossil Source Contribution to Brown Carbon in Beijing During Winter

Overview

Journal Sci Rep

Specialty Science

Date 2017 Mar 8

PMID 28266611

Citations 9

Authors

Caiqing Yan

Mei Zheng

Carme Bosch

August Andersson

Yury Desyaterik

Amy P Sullivan

Jeffrey L Collett

Bin Zhao

Shuxiao Wang

Kebin He

Orjan Gustafsson

Affiliations

Soon will be listed here.

Abstract

Organic aerosol (OA) constitutes a substantial fraction of fine particles and affects both human health and climate. It is becoming clear that OA absorbs light substantially (hence termed Brown Carbon, BrC), adding uncertainties to global aerosol radiative forcing estimations. The few current radiative-transfer and chemical-transport models that include BrC primarily consider sources from biogenic and biomass combustion. However, radiocarbon fingerprinting here clearly indicates that light-absorbing organic carbon in winter Beijing, the capital of China, is mainly due to fossil sources, which contribute the largest part to organic carbon (OC, 67 ± 3%) and its sub-constituents (water-soluble OC, WSOC: 54 ± 4%, and water-insoluble OC, WIOC: 73 ± 3%). The dual-isotope (ΔC/δC) signatures, organic molecular tracers and Beijing-tailored emission inventory identify that this fossil source is primarily from coal combustion activities in winter, especially from the residential sector. Source testing on Chinese residential coal combustion provides direct evidence that intensive coal combustion could contribute to increased light-absorptivity of ambient BrC in Beijing winter. Coal combustion is an important source to BrC in regions such as northern China, especially during the winter season. Future modeling of OA radiative forcing should consider the importance of both biomass and fossil sources.

Citing Articles

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