JpGU-AGU Joint Meeting 2020

講演情報

[E] ポスター発表

セッション記号 A (大気水圏科学) » A-AS 大気科学・気象学・大気環境

[A-AS07] 大気化学

コンビーナ:齋藤 尚子(千葉大学環境リモートセンシング研究センター)、中山 智喜(長崎大学 大学院水産・環境科学総合研究科)、豊田 栄(東京工業大学物質理工学院)、内田 里沙(一般財団法人 日本自動車研究所)

[AAS07-P26] Comparison of compositional characteristics of aerosol and rainwater samples collected in Nagoya

*魏 辰然1Afsana Sonia1陳 慶彩2Deshmukh Dhananjay3河村 公隆3持田 陸宏1,4 (1.名古屋大学環境学研究科、2.陕西科技大学、3.中部大学・中部高等学術研究所、4.名古屋大学宇宙地球環境研究所)

Organic aerosol is one of major components of atmospheric aerosol particles. Some volatile organic compounds (VOCs) react in the aqueous-phase of cloud droplets, and after the evaporation of liquid water, they form aerosol, which is called aqueous secondary organic aerosol (aqSOA). Further, organic aerosols may also change to aqSOA through aging in the aqueous phase. Although a number of laboratory experiments and model simulations have explored the mechanism of aqSOA formation, the mechanism in real atmospheric environments is still unclear. To find a clue to understand how aqSOA is formed in could droplets through aqueous-phase reactions, this study compares compositional characteristics of water-soluble components in aerosol and rainwater samples, as a means to compare the components of aerosols before and after the reactions in the real atmosphere.

Aerosol and rainwater samples were collected on campus of Nagoya University in Nagoya, Japan. The organics therein were fractionated into humic-like substances with a neutral nature (HULIS-n), humic-like substances with an acid nature (HULIS-a) and high-polar water-soluble organic matter (HP-WSOM). The optical properties of the samples were measured using a fluorescence spectrophotometer and an ultraviolet-visible spectrophotometer. Fourier transform infrared spectroscopy (FT-IR) was used to compare the chemical structural characteristics of aerosol and rainwater samples.

The analysis of the 3D fluorescence spectra shows that the HULIS-n-to-HULIS-a ratios based on the fluorescence intensity of two spectra regions (excitation wavelength from 240 to 260 nm and emission wavelength from 400 to 460 nm , and excitation wavelength from 320 to 360 nm and emission wavelength from 420 to 460 nm) from aerosol samples were in most cases larger than those of rainwater. A possible explanation is that some of the low-polar fluorescent substances (fluorescent substances in HULIS-n) were decomposed to non-fluorescent substances and that more-polar fluorescent substances (fluorescent substances in HULIS-a) were formed by aqueous-phase reactions. The FT-IR results present that HULIS-n and HULIS-a in aerosol samples show a smaller fraction of carboxyl group but a larger fraction of carbonyl group than those in rainwater samples, implying that the oxidation of carbonyl groups to carboxyl groups occured for HULIS-n and HULIS-a, and/or that aqSOA containing carboxyl group was formed from VOCs. Because the presence of water in the samples for the FT-IR analysis may have influenced on the quantification of functional groups, compositional characteristics of aerosol and rainwater samples should be further compared using other instruments such as an aerosol mass spectrometer.