Photochemical production and loss of organic acids in high Arctic aerosols during long range transport and polar sunrise ozone depletion events

Kawamura Kimitaka; Imai Yoshie; Barrie Leonard A.

Title	en Photochemical production and loss of organic acids in high Arctic aerosols during long range transport and polar sunrise ozone depletion events
Creator	en Kawamura, Kimitaka NRID 1000070201449 en Imai, Yoshie en Barrie, Leonard A.
Accessrights	open access
Subject	Other en Dicarboxylic acids Other en long-range transport Other en photochemical production Other en polar sunrise Other en vanadium Other en bromine NDC 451.3
Description	Abstract en Unique daily measurements of water-soluble organics in fine (< 2 μm) and coarse (> 2 μm) aerosols were conducted at Alert in the Canadian Arctic in winter to spring of 1992. They yield insight into photochemical production and loss of organics during long-range transport and ozone depletion events following polar sunrise. Comprehensive analyses of a,w-dicarboxylic acids (C2-C12), w-oxocarboxylic acids (C2-C9) and a-dicarbonyls (C2, C3) as well as pyruvic acid and aromatic (phthalic) diacid were conducted using GC and GC/MS techniques. Oxalic (C2) acid was generally the dominant diacid species in both fine and coarse fractions, followed by malonic (C3) and succinic (C4) acids. Concentrations of total diacids in the fine aerosol fraction (0.2-64 ngm-3) were 5-60 times higher than those in the coarse fraction (0.01-3 ngm-3). After polar sunrise in early March, the total concentration of fine aerosol diacids increased by a factor of 3 to 5 while the coarse mode did not change significantly. From dark winter to sunlit spring, temporal changes in correlations and ratios of these water-soluble organics to vanadium and sulfate measured simultaneously suggest that atmospheric diacids and related organic compounds are largely controlled by long-range atmospheric transport of polluted air during winter, but they are significantly affected by photochemical production. The latter can occur in sunlight either during transport to the Arctic or during photochemical events associated with surface ozone depletion and bromine chemistry near Alert in spring. Conversion of gaseous precursors to particulate matter via photochemical oxidation was intensified at polar sunrise, resulting in a peak in the ratio of total diacids to V. During ozone depletion events, complex patterns are indicated in photochemical production and loss depending on the diacid compound. Unsaturated (maleic and phthalic) diacids were inversely correlated with particulate Br whereas saturated diacids (C2-C4) positively correlated with particulate Br. These results suggest that Br chemistry associated with ozone depletion leads to degradation of unsaturated diacids and to the production of smaller saturated diacids.
Publisher	en Elsevier
Date	Issued2005-02
Language	eng
Resource Type	journal article
Version Type	AM
Identifier	HDL http://hdl.handle.net/2115/10508
Relation	URI http://www.sciencedirect.com/science/journal/13522310 isVersionOf DOI https://doi.org/10.1016/j.atmosenv.2004.10.020
Journal	PISSN 13522310 en Atmospheric Environment Volume Number39 Issue Number4 Page Start599 Page End614
File	fulltext KawamuraAE2005.pdf 1.01 MB (application/pdf) Issued2005-02
Oaidate	2023-07-26