Methanesulphonic acid in aerosols along a cruise path from China to the Arctic Ocean: Spatial and temporal distributions and link with iodine

doi:10.13679/j.advps.2015.3.00222

Abstract

Abstract: Methanesulphonic acid (MSA) may play an important role in the climate change occurring in response to the warming of the Arctic Ocean. However, the spatial and temporal distributions of MSA in this region are poorly understood. We report on the MSA content of aerosols over oceans measured during the 3rd Chinese National Arctic Research Expedition (CHINARE2008) from July to September, 2008. Results show that the aerosol MSA content can be influenced by multiple processes in different areas. In coastal regions, airborne pollutants, especially nitric oxide, may strongly influence the oxidation of dimethyl sulfide (DMS) and increase the concentration of aerosol MSA. In remote areas of the Pacific and Arctic oceans, changes in plankton will indirectly influence the airborne MSA concentration. Moreover, we found fairly similar trends in the variation of the concentrations of total iodine (TI) and MSA in the Arctic during CHINARE2008, suggesting that iodine and MSA may come from similar sources in the Arctic. Compared with the findings from other two cruises, CHINARE1999 and CHINARE2012, we found that sea ice is an extremely important factor that influences the aerosol MSA content in the Arctic. In addition, MSA concentrations may increase in the Arctic in the future caused by sea ice melting due to global warming.

Key words: Arctic, MSA, iodine, phytoplankton, sea ice

LIU Haoran XIE Zhouqing YE Peipei KANG Hui XU Siqi. Methanesulphonic acid in aerosols along a cruise path from China to the Arctic Ocean: Spatial and temporal distributions and link with iodine[J]. ADVANCES IN POLAR SCIENCE, DOI: 10.13679/j.advps.2015.3.00222.

References

1 Andreae M O, Raemdonck H. Dimethyl sulfide in the surface ocean and the marine atmosphere: a global view. Science, 1983, 221(4612):
744–747
2 Ayers G P, Ivey J P, Gillett R W. Coherence between seasonal cycles of dimethyl sulphide, methanesulphonate and sulphate in marine air. Nature, 1991, 349(6308): 404–406
3 Bates T S, Cline J D, Gammon R H, et al. Regional and seasonal variations in the flux of oceanic dimethylsulfide to the atmosphere. J Geophys Res, 1987, 92(C3): 2930–2938
4 Koch D, Jacob D, Tegen I, et al. Tropospheric sulfur simulation and sulfate direct radiative forcing in the Goddard Institute for Space Studies general circulation model. J Geophys Res, 1999, 104(D19):
23799–23822
5 Buat-Ménard P. The role of air-sea exchange in geochemical cycling. New York: Springer Science & Business Media, 2012, 185
6 O’Dowd C D, Smith M H, Consterdine I E, et al. Marine aerosol, seasalt, and the marine Sulphur cycle: A short review. Atmos Environ, 1997, 31(1): 73–80
7 Shaw G E. Bio-controlled thermostasis involving the sulfur cycle. Clim Change, 1983, 5(3): 297–303
8 Clarke A D, Davis D, Kapustin V N, et al. Particle nucleation in the tropical boundary layer and its coupling to marine sulfur sources. Science, 1998, 282(5386): 89–92
9 Charlson R J, Lovelock J E, Andreae M O, et al. Oceanic phytoplankton, atmospheric sulphur, cloud albedo and climate. Nature, 1987, 326(6114): 655–661
10 Savoie D L, Arimoto R, Keene W C, et al. Marine biogenic and anthropogenic contributions to non-sea-salt sulfate in the marine boundary layer over the North Atlantic Ocean. J Geophys Res, 2002, 107(D18): 4356
11 Curran M A J, Van Ommen T D, Morgan V I, et al. Ice core evidence for Antarctic sea ice decline since the 1950s. Science, 2003, 302(5648): 1203–1206
12 Legrand M, Saigne C F. Methanesulfonic acid in south polar snow layers: A record of strong El Nino? Geophys Res Lett, 1991, 18(2): 187–190
13 Davis D, Chen G, Bandy A, et al. Dimethyl sulfide oxidation in the equatorial pacific: comparison of model simulations with field observations for DMS, SO2, H2SO4(g), msa(g), MS and NSS. J
Geophys Res, 1999, 104(D5): 5765–5784
14 Sturges W T, Shaw G E. Halogens in aerosols in central Alaska.
Atmos Environ Part A, 1993, 27(17–18): 2969–2977
15 Stefels J, Van Boekel W H M. Production of DMS from dissolved DMSP in axenic cultures of the marine phytoplankton species Phaeocystis sp. Mar Ecol Prog Ser, 1993, 97(1): 11–18
16 Quack B, Wallace D W R. Air-sea flux of bromoform: Controls, rates, and implications. Global Biogeochem Cycles, 2003, 17(1): 1023
17 Salawitch R J. Atmospheric chemistry: biogenic bromine. Nature,
2006, 439(7074): 275–277
18 Lovelock J E. Natural halocarbons in the air and in the sea. Nature, 1975, 256(5514): 193–194
19 Saltzman E S, Savoie D L, Prospero J M, et al. Methanesulfonic acid and non-sea-salt sulfate in Pacific air: Regional and seasonal variations. J Atmos Chem, 1986, 4(2): 227–240
20 Li S M, Barrie L A. Biogenic sulfur aerosol in the Arctic troposphere: 1. Contributions to total sulfate. J Geophys Res, 1993, 98(D11): 20613–20622
21 Gao Y, Arimoto R, Duce R A, et al. Atmospheric non-sea-salt sulfate, nitrate and methanesulfonate over the China Sea. J Geophys Res, 1996, 101(D7): 12601–12611
22 Mthalopoulos N, Nguyen B C, Boissard C, et al. Field study of dimethylsulfide oxibation in the boundary layer: Variations of dimethylsulfide, methanesulfonic acid, sulfur dioxide, non-sea-salt
sulfate and aitken nuclei at a coastal site. J Atmos Chem, 1992, 14(1): 459–477
23 Xie Z Q, Sun L G, Jihong C D. Non-sea-salt sulfate in the marine boundary layer and its possible impact on chloride depletion. Acta Oceanol Sin, 2005, 24(6): 162–171
24 Ye P P, Xie Z Q, Yu J, et al. Spatial distribution of methanesulphonic acid in the arctic aerosol collected during the Chinese Arctic Research Expedition. Atmosphere, 2015, 6(5): 699–712, doi: 10.3390/atmos6050699.
25 Leck C, Persson C. Seasonal and short-term variability in dimethyl sulfide, sulfur dioxide and biogenic sulfur and sea salt aerosol particles in the arctic marine boundary layer during summer and
autumn. Tellus B, 1996, 48(2): 272–299
26 Jenkins A,Dutrieux P, Jacobs S S, et al. Observations beneath PineIsland Glacier in West Antarctica and implications for its retreat. Nat Geosci, 2010, 3(7): 468–472
27 Barnard W R, Andreae M O, IversonR L. Dimethylsulfide and Phaeocystis poucheti in the southeastern Bering Sea. Cont Shelf Res, 1984, 3(2):103–113
28 Arrigo K R, Van Dijken G L. Annual changes in sea-ice, chlorophyll a, and primary production in the Ross Sea, Antarctica. Deep Sea Res Part II: Top Stud Oceanogr, 2004, 51(1–3): 117–138
29 NSIDC. Arctic sea ice news & analysis: Arctic sea ice now second lowest\ on record. http://nsidcorg/arcticseaicenews/2008/082608html, 2008
30 Kwok R, Rothrock D A. Decline in Arctic sea ice thickness from submarine and ICESat records: 1958–2008. Geophys Res Lett, 2009, 36(15):L15501
31 Savoie D L, Prospero J M, Saltzman E S. Non-sea-salt sulfate and nitrate in trade wind aerosols at Barbados: Evidence for long-range transport. J Geophys Res, 1989, 94(D4): 5069–5080
32 Mukai H, Yokouchi Y, Suzuki M. Seasonal variation of methanesulfonic acid in the atmosphere over the Oki Islands in the sea of Japan. Atmos Environ, 1995, 29(14):1637–1648
33 Turner S M, Malin G, Liss P S, et al. The seasonal variation of dimethyl sulfide and dimethylsulfoniopropionate concentrations in nearshore waters. Limnol Oceanogr, 1988, 33(3): 364–375
34 Mukai H, Ambe Y, Shibata K, et al. Long-term variation of chemical composition of atmospheric aerosol on the Oki Islands in the Sea of Japan. Atmos Environ, 1990, 24(6): 1379–1390
35 Jensen N R, Hjorth J, Lohse C, et al. Products and mechanism of the reaction between NO3 and dimethylsulphide in air. Atmos Environ, 1991, 25(9): 1897–1904
36 Yuan H, Wang Y, Zhuang G S. The MSA concentration of aerosols in Beijing. Chin Sci Bull, 2004, 49(8): 744–749 (in Chinese)
37 Yin F D, Grosjean D, Seinfeld J H. Photooxidation of dimethyl sulfide and dimethyl disulfide. I: Mechanism development. J Atmos Chem, 1990, 11(4): 309–364
38 Zhang X Y, Zhuang G S, Guo J H, et al. Characterization of aerosol over the Northern South China Sea during two cruises in 2003. Atmos Environ, 2007, 41(36): 7821–7836
39 Sturges W T, Cota G F, Buckley P T. Bromoform emission from Arctic ice algae. Nature, 1992, 358(6388): 660–662
40 Tokarczyk R, Moore R M. Production of volatile organohalogens by phytoplankton cultures. Geophys Res Lett, 1994, 21(4): 285–288
41 Belviso S, Moulin C, Bopp L, et al. Assessment of a global climatology of oceanic dimethylsulfide (DMS) concentrations based on SeaWiFS imagery (1998–2001). Can J Fisheries Aquat Sci, 2004,
61(5): 804–816
42 Vogt M, Liss P S. Dimethylsulfide and climate // Le Quéré C, Saltzman E S. Surface ocean-lower atmosphere processes. Geophysical Monograph Series, 2009, 198: 197–232
43 Xu S Q, Xie Z Q, Li B, et al. Iodine speciation in marine aerosols along a 15 000-km round-trip cruise path from Shanghai, China, to the Arctic Ocean. Environ Chem, 2010, 7(5): 406–412
44 Leck C, Persson C. The central Arctic Ocean as a source of dimethyl sulfide Seasonal variability in relation to biological activity. Tellus B, 1996, 48(2): 156–177
45 Hara K, Osada K, Hayashi M, et al. Variation of concentrations of sulfate, methanesulfonate and sulfur dioxide at Ny-Ålesund in 1995/96 winter. Proc NIPR Symp Polar Meteorol Glaciol, 1997, 11:
127–137
46 Clarke D B, Ackley S F. Sea ice structure and biological activity in the Antarctic marginal ice zone. J Geophys Res, 1984, 89(C2): 2087–2095
47 Stroeve J, Frei A, Mc Creight J, et al. Arctic sea-ice variabilityrevisited. Ann Glaciol, 2008, 48(1): 71–81
48 Lu P, Li Z J, Cheng B, et al. Sea ice surface features in Arctic summer 2008: Aerial observations. Remote Sens Environ, 2010, 114(4): 693–699
49 Nakamura T, Matsumoto K, Uematsu M. Chemical characteristics of aerosols transported from Asia to the East China Sea: an evaluation of anthropogenic combined nitrogen deposition in autumn. Atmos Environ, 2005, 39(9): 1749–1758

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