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Atmospheric HCH concentrations over the Marine Boundary Layer from Shanghai, China to the Arctic Ocean: role of human activity and climate change.

https://arctichealth.org/en/permalink/ahliterature100196
Source
Environ Sci Technol. 2010 Nov 15;44(22):8422-8
Publication Type
Article
Date
Nov-15-2010
Author
Xiaoguo Wu
James C W Lam
Chonghuan Xia
Hui Kang
Liguang Sun
Zhouqing Xie
Paul K S Lam
Author Affiliation
Institute of Polar Environment, School of Earth and Space Sciences, University of Science and Technology of China, Hefei, Anhui, 230026, People's Republic of China.
Source
Environ Sci Technol. 2010 Nov 15;44(22):8422-8
Date
Nov-15-2010
Language
English
Publication Type
Article
Abstract
From July to September 2008, air samples were collected aboard the research expedition icebreaker XueLong (Snow Dragon) as part of the 2008 Chinese Arctic Research Expedition Program. Hexachlorocyclohexane (HCH) concentrations were analyzed in all of the samples. The average concentrations (? standard deviation) over the entire period were 33 ? 16, 5.4 ? 3.0, and 13 ? 7.5 pg m?? for a-, ?- and ?-HCH, respectively. Compared to previous studies in the same areas, total HCH (SHCH, the sum of a-, ?-, and ?-HCH) levels declined by more than 10 ? compared to those observed in the 1990s, but were approximately 4 ? higher than those measured by the 2003 China Arctic Research Expedition, suggesting the increase of atmospheric SHCH recently. Because of the continuing use of lindane, ratios of a/?-HCH showed an obvious decrease in North Pacific and Arctic region compared with those for 2003 Chinese Arctic Research Expedition. In Arctic, the level of a-HCH was found to be linked to sea ice distribution. Geographically, the average concentration of a-HCH in air samples from the Chukchi and Beaufort Seas, neither of which contain sea ice, was 23 ? 4.4 pg m??, while samples from the area covered by seasonal ice (~75?N to ~83?N), the so-called "floating sea ice region", contained the highest average levels of a-HCH at 48 ? 12 pg m??, likely due to emission from sea ice and strong air-sea exchange. The lowest concentrations of a-HCH were observed in the pack ice region in the high Arctic covered by multiyear sea ice (~83?N to ~86?N). This phenomenon implies that the re-emission of HCH trapped in ice sheets and Arctic Ocean may accelerate during the summer as ice coverage in the Arctic Ocean decreases in response to global climate change.
PubMed ID
20977270 View in PubMed
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d(13)C-CH4 reveals CH4 variations over oceans from mid-latitudes to the Arctic.

https://arctichealth.org/en/permalink/ahliterature265870
Source
Sci Rep. 2015;5:13760
Publication Type
Article
Date
2015
Author
Juan Yu
Zhouqing Xie
Liguang Sun
Hui Kang
Pengzhen He
Guangxi Xing
Source
Sci Rep. 2015;5:13760
Date
2015
Language
English
Publication Type
Article
Abstract
The biogeochemical cycles of CH4 over oceans are poorly understood, especially over the Arctic Ocean. Here we report atmospheric CH4 levels together with d(13)C-CH4 from offshore China (31°N) to the central Arctic Ocean (up to 87°N) from July to September 2012. CH4 concentrations and d(13)C-CH4 displayed temporal and spatial variation ranging from 1.65 to 2.63 ppm, and from -50.34% to -44.94% (mean value: -48.55?±?0.84%), respectively. Changes in CH4 with latitude were linked to the decreasing input of enriched d(13)C and chemical oxidation by both OH and Cl radicals as indicated by variation of d(13)C. There were complex mixing sources outside and inside the Arctic Ocean. A keeling plot showed the dominant influence by hydrate gas in the Nordic Sea region, while the long range transport of wetland emissions were one of potentially important sources in the central Arctic Ocean. Experiments comparing sunlight and darkness indicate that microbes may also play an important role in regional variations.
PubMed ID
26323236 View in PubMed
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Detection of organosulfates and nitrooxy-organosulfates in Arctic and Antarctic atmospheric aerosols, using ultra-high resolution FT-ICR mass spectrometry.

https://arctichealth.org/en/permalink/ahliterature303795
Source
Sci Total Environ. 2021 May 01; 767:144339
Publication Type
Journal Article
Date
May-01-2021
Author
Yuqing Ye
Haicong Zhan
Xiawei Yu
Juan Li
Xinming Wang
Zhouqing Xie
Author Affiliation
Institute of Polar Environment & Anhui Key Laboratory of Polar Environment and Global Change, School of Earth and Space Sciences & Department of Environmental Science and Engineering, University of Science and Technology of China, Hefei, Anhui 230026, China.
Source
Sci Total Environ. 2021 May 01; 767:144339
Date
May-01-2021
Language
English
Publication Type
Journal Article
Abstract
Organosulfates (OSs) are recognized as important secondary organic aerosols (SOAs) in recent years. Due to their amphipathy and light absorptive capacity, OSs may potentially impact climate. Moreover, OSs can serve as molecular tracers for precursors and multiple processes leading to the generation of SOA. However, studies on OSs are lacking in the polar regions which limits our understanding of both their formation pathways and impacts on the polar environment. Here we present the first investigation into OSs in both the Arctic and Antarctic. Organic compounds in aerosol samples collected from the polar regions during the 2013/2014 Chinese National Arctic/Antarctic Research Expedition (CHINARE) were analyzed by Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR-MS) coupled with negative ion mode electrospray ionization (ESI(-)). Hundreds to thousands of OSs were detected at the polar sampling sites. The estimated total concentrations of OSs were in the range of 46-670 ng/m3 in the Arctic sampling area, and 47-260 ng/m3 in the Antarctic sampling area, accounting for 1-16% of total OM. OSs were found to have undergone a high degree of oxidation in the aerosol samples, which might be due to the combined effects of enhanced photo-oxidation in summertime or continuous oxidation during transport to the polar region. The potential appointment of OS precursors highlights the important role of long-range air-mass transport on the OSs derived from biogenic precursors and a notably large contribution from anthropogenic emissions, suggesting that human activities have significant impacts in remote polar environments. The results of this study provide important insights into the characteristics of OSs in the polar atmosphere. However, the need for further research focusing on the quantification, formation mechanisms and impacts of OSs on climate is emphasized.
PubMed ID
33434833 View in PubMed
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Historical records and contamination assessment of potential toxic elements (PTEs) over the past 100 years in Ny-Ă…lesund, Svalbard.

https://arctichealth.org/en/permalink/ahliterature305231
Source
Environ Pollut. 2020 Nov; 266(Pt 1):115205
Publication Type
Journal Article
Date
Nov-2020
Author
Zhongkang Yang
Linxi Yuan
Zhouqing Xie
Jun Wang
Zhaolei Li
Luyao Tu
Liguang Sun
Author Affiliation
Institute of Polar Environment & Anhui Key Laboratory of Polar Environment and Global Change, Department of Environmental Science and Engineering, University of Science and Technology of China, Hefei, 230026, China; College of Resources and Environment, Key Laboratory of Agricultural Environment in Universities of Shandong, Shandong Agricultural University, Tai'an, 271000, China.
Source
Environ Pollut. 2020 Nov; 266(Pt 1):115205
Date
Nov-2020
Language
English
Publication Type
Journal Article
Keywords
Environmental monitoring
Metals, Heavy - analysis
Risk assessment
Soil
Soil Pollutants - analysis
Svalbard
Abstract
Ny-Ålesund has been significantly impacted by anthropogenic activities (e.g. coal mining, scientific research, tourist shipping) over the past 100 years. However, the studies of potential toxic elements (PTEs) contamination in Ny-Ålesund currently mainly focus on surface soil or surface fjord sediments, and little is known about the history and status of PTEs contamination over the past 100 years. In this study, we collected a palaeo-notch sediment profile YN, analyzed the contents of six typical PTEs (Cu, Pb, Cd, Hg, As, Se) in the sediments, and assessed the historical pollution status in Ny-Ålesund using the pollution load index, geo-accumulation index and enrichment factor. The results showed that the contents of PTEs over the past 100 years increased rapidly compared with those during the interval of 9400-100 BP. In addition, Pb, Cd and Hg showed a clear signal of enrichment and were the main polluters among the PTEs analyzed. The contamination was likely linked to gas-oil powered generators, coal mining, research station, tourist shipping and long-range transport of pollutants.
PubMed ID
32707354 View in PubMed
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Methyl iodine over oceans from the Arctic Ocean to the maritime Antarctic.

https://arctichealth.org/en/permalink/ahliterature272839
Source
Sci Rep. 2016;6:26007
Publication Type
Article
Date
2016
Author
Qihou Hu
Zhouqing Xie
Xinming Wang
Juan Yu
Yanli Zhang
Source
Sci Rep. 2016;6:26007
Date
2016
Language
English
Publication Type
Article
Abstract
Studies about methyl iodide (CH3I), an important atmospheric iodine species over oceans, had been conducted in some maritime regions, but the understanding of the spatial distribution of CH3I on a global scale is still limited. In this study, we reports atmospheric CH3I over oceans during the Chinese Arctic and Antarctic Research Expeditions. CH3I varied considerably with the range of 0.17 to 2.9 pptv with absent of ship emission. The concentration of CH3I generally decreased with increasing latitudes, except for higher levels in the middle latitudes of the Northern Hemisphere than in the low latitudes. For sea areas, the Norwegian Sea had the highest CH3I concentrations with a median of 0.91 pptv, while the Central Arctic Ocean had the lowest concentrations with all values below 0.5 pptv. CH3I concentration over oceans was affected by many parameters, including sea surface temperature, salinity, dissolved organic carbon, biogenic emissions and input from continents, with distinctive dominant factor in different regions, indicating complex biogeochemical processes of CH3I on a global scale.
PubMed ID
27184471 View in PubMed
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Monocarboxylic and dicarboxylic acids over oceans from the East China Sea to the Arctic Ocean: Roles of ocean emissions, continental input and secondary formation.

https://arctichealth.org/en/permalink/ahliterature292182
Source
Sci Total Environ. 2018 May 30; 640-641:284-292
Publication Type
Journal Article
Date
May-30-2018
Author
Qihou Hu
Zhouqing Xie
Xinming Wang
Hui Kang
Yuqing Zhang
Xiang Ding
Pengfei Zhang
Author Affiliation
Key Lab of Environmental Optics and Technology, Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Hefei, 230031, China.
Source
Sci Total Environ. 2018 May 30; 640-641:284-292
Date
May-30-2018
Language
English
Publication Type
Journal Article
Abstract
Organic acids are major components in marine organic aerosols. Many studies on the occurrence, sources and sinks of organic acids over oceans in the low and middle latitudes have been conducted. However, the understanding of relative contributions of specific sources to organic acids over oceans, especially in the high latitudes, is still inadequate. This study measured organic acids, including C14:0 - C32:0 saturated monocarboxylic acids (MCAs), C16:1, C18:1 and C18:2 unsaturated MCAs, and di-C4 - di-C10 dicarboxylic acids (DCAs), in the marine boundary layer from the East China Sea to the Arctic Ocean during the 3rd Chinese Arctic Research Expedition (CHINARE 08). The average concentrations were 18?±?16?ng/m3 and 11?±?5.4?ng/m3 for SMCA and SDCA, respectively. The levels of saturated MCAs were much higher than those of unsaturated DCAs, with peaks at C16:0, C18:0 and C14:0. DCAs peaked at di-C4, followed by di-C9 and di-C8. Concentrations of MCAs and DCAs generally decreased with increasing latitudes. Sources of MCAs and DCAs were further investigated using principal component analysis with a multiple linear regression (PCA-MLR) model. Overall, carboxylic acids originated from ocean emissions, continental input (including biomass burning, anthropogenic emissions and terrestrial plant emissions), and secondary formation. All the five sources contributed to MCAs with ocean emissions as the predominant source (48%), followed by biomass burning (20%). In contrast, only 3 sources (i.e., secondary formation (50%), anthropogenic emissions (41%) and biomass burning (9%)) contributed to DCAs. Furthermore, the sources varied with regions. Over the Arctic Ocean, only secondary formation and anthropogenic emissions contributed to MCAs and DCAs.
PubMed ID
29859444 View in PubMed
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Volatilization of polycyclic aromatic hydrocarbons (PAHs) over the North Pacific and adjacent Arctic Ocean: The impact of offshore oil drilling.

https://arctichealth.org/en/permalink/ahliterature304289
Source
Environ Pollut. 2021 Jan 01; 268(Pt B):115963
Publication Type
Journal Article
Date
Jan-01-2021
Author
Afeng Chen
Xiaoguo Wu
Staci L Massey Simonich
Hui Kang
Zhouqing Xie
Author Affiliation
Institute of Polar Environment & Anhui Key Laboratory of Polar Environment and Global Change, Department of Environmental Science and Engineering, University of Science and Technology of China, Hefei, Anhui, 230026, PR China; Anhui Provincial Engineering Laboratory of Water and Soil Pollution Control and Remediation, School of Ecology and Environment, Anhui Normal University, Wuhu, Anhui, 241002, PR China.
Source
Environ Pollut. 2021 Jan 01; 268(Pt B):115963
Date
Jan-01-2021
Language
English
Publication Type
Journal Article
Keywords
Air Pollutants - analysis
Arctic Regions
Environmental monitoring
Oceans and Seas
Pacific Ocean
Polycyclic Aromatic Hydrocarbons - analysis
Volatilization
Abstract
Air and seawater samples were collected in 2016 over the North Pacific Ocean (NPO) and adjacent Arctic Ocean (AO), and Polycyclic Aromatic Hydrocarbons (PAHs) were quantified in them. Atmospheric concentrations of ?15 PAHs (gas + particle phase) were 0.44-7.0 ng m-3 (mean = 2.3 ng m-3), and concentrations of aqueous ?15 PAHs (dissolved phase) were 0.82-3.7 ng L-1 (mean = 1.9 ng L-1). Decreasing latitudinal trends were observed for atmospheric and aqueous PAHs. Results of diagnostic ratios suggested that gaseous and aqueous PAHs were most likely to be related to the pyrogenic and petrogenic sources, respectively. Three sources, volatilization, coal and fuel oil combustion, and biomass burning, were determined by the PMF model for gaseous PAHs, with percent contributions of 10%, 44%, and 46%, respectively. The 4- ring PAHs underwent net deposition during the cruise, while some 3- ring PAHs were strongly dominated by net volatilization, even in the high latitude Arctic region. Offshore oil/gas production activities might result in the sustained input of low molecular weight 3- ring PAHs to the survey region, and further lead to the volatilization of them. Compared to the gaseous exchange fluxes, fluxes of atmospheric dry deposition and gaseous degradation were negligible. According to the extrapolated results, the gaseous exchange of semivolatile aromatic-like compounds (SALCs) may have a significant influence on the carbon cycling in the low latitude oceans, but not for the high latitude oceans.
PubMed ID
33162218 View in PubMed
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7 records – page 1 of 1.