Measurement report: Summertime fluorescence characteristics of atmospheric water-soluble organic carbon in the marine boundary layer of the western Arctic Ocean

Jung, Jinyoung; Miyazaki, Yuzo; Hur, Jin; Lee, Yun Kyung; Jeon, Mi Hae; Lee, Youngju; Cho, Kyoung-Ho; Chung, Hyun Young; Kim, Kitae; Choi, Jung-Ok; Lalande, Catherine; Kim, Joo-Hong; Choi, Taejin; Yoon, Young Jun; Yang, Eun Jin; Kang, Sung-Ho

doi:10.5194/acp-23-4663-2023

Cited by 2 publications

(1 citation statement)

References 150 publications

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“…Li et al (2023) demonstrated that HIX correlates well with secondary formation factors. Jung et al (2023) found a strong correlation between humic-like/protein-like ratios and HIX. In contrast, we observed a significant negative correlation between C3/(C1+C2) and HIX (Spearman's coefficient = −0.92, p < 0.01), indicating that the C3/ (C1+C2) ratio is a useful indicator of primary sources of chromophores.…”

Section: Fluorescence Components Characteristicsmentioning

confidence: 85%

Seasonal changes in water-soluble brown carbon (BrC) at Nanling background station in South China

Zhang,

Tang,

Geng

et al. 2024

Front. Environ. Sci.

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Brown carbon (BrC) is an important light-absorbing component of organic carbon (OC), causing large uncertainty in aerosol radiative forcing evaluation and being related to health issues as well. Knowledge of BrC in an atmospheric background station is beneficial to understand its role in a changing climate. A year-long sampling campaign was conducted at Nanling background station to get a comprehensive knowledge of WS-BrC, a total of seventy-two PM2.5 samples throughout a year were used. Light absorption and fluorescence spectra of WSOC were analyzed synchronously using a fluorescence spectrophotometer. The low levels of PM2.5, OC, and elemental carbon (EC) conferred a background site. The optical properties of WS-BrC were characterized using excitation-emission matrix (EEM) fluorescence spectroscopy. The WS-BrC made a significant contribution (365 nm, 18% ± 10%) to total carbonaceous aerosol absorption. The mass absorption efficiency (MAE) of WS-BrC is 0.81 ± 0.34 m2 gC–1, and varies among seasons due to the different sources or atmospheric processing. Three EEM fluorescent components were identified by parallel factor (PAFAFAC) analysis, including two humic-like substances (HULIS, C1, C2), and one phenolic-like component. The HULIS components accounted for approximately 70% of the total fluorescence intensities. Primary combustion emissions showed enhanced activity during the winter and spring seasons, but there were no significant influences on WS-BrC in spring. Secondary sources contributed significantly to WS-BrC during winter, summer, and autumn (all exceeding 50%), except for spring. Photooxidation is a significant process in the formation of secondary WS-BrC in winter and autumn, but there may be another formation pathway in summer, i.e., the ammonia pathway. This study contributes to our understanding of BrC in the background atmosphere.

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Section: Fluorescence Components Characteristicsmentioning

confidence: 85%

Seasonal changes in water-soluble brown carbon (BrC) at Nanling background station in South China

Zhang,

Tang,

Geng

et al. 2024

Front. Environ. Sci.

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Characteristics and sources of fluorescent aerosols in the central Arctic Ocean

Beck,

Moallemi,

Heutte

et al. 2024

Elem Sci Anth

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The Arctic is sensitive to cloud radiative forcing. Due to the limited number of aerosols present throughout much of the year, cloud formation is susceptible to the presence of cloud condensation nuclei and ice nucleating particles (INPs). Primary biological aerosol particles (PBAP) contribute to INPs and can impact cloud phase, lifetime, and radiative properties. We present yearlong observations of hyperfluorescent aerosols (HFA), tracers for PBAP, conducted with a Wideband Integrated Bioaerosol Sensor, New Electronics Option during the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition (October 2019–September 2020) in the central Arctic. We investigate the influence of potential anthropogenic and natural sources on the characteristics of the HFA and relate our measurements to INP observations during MOSAiC. Anthropogenic sources influenced HFA during the Arctic haze period. But surprisingly, we also found sporadic “bursts” of HFA with the characteristics of PBAP during this time, albeit with unclear origin. The characteristics of HFA between May and August 2020 and in October 2019 indicate a strong contribution of PBAP to HFA. Notably from May to August, PBAP coincided with the presence of INPs nucleating at elevated temperatures, that is, >−9°C, suggesting that HFA contributed to the “warm INP” concentration. The air mass residence time and area between May and August and in October were dominated by the open ocean and sea ice, pointing toward PBAP sources from within the Arctic Ocean. As the central Arctic changes drastically due to climate warming with expected implications on aerosol–cloud interactions, we recommend targeted observations of PBAP that reveal their nature (e.g., bacteria, diatoms, fungal spores) in the atmosphere and in relevant surface sources, such as the sea ice, snow on sea ice, melt ponds, leads, and open water, to gain further insights into the relevant source processes and how they might change in the future.

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Measurement report: Summertime fluorescence characteristics of atmospheric water-soluble organic carbon in the marine boundary layer of the western Arctic Ocean

Cited by 2 publications

References 150 publications

Seasonal changes in water-soluble brown carbon (BrC) at Nanling background station in South China

Seasonal changes in water-soluble brown carbon (BrC) at Nanling background station in South China

Characteristics and sources of fluorescent aerosols in the central Arctic Ocean

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