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Yin Xijie, Sun Zhilei, Xu Yonghang, Li Yunhai, Shao Changwei. Measurement of sulfate reduction rate in coastal sediments of Jiulong River Estuary with a radiotracer technique[J]. Haiyang Xuebao, 2015, 37(4): 83-93. doi: 10.3969/j.issn.0253-4193.2015.04.008
Citation: Yin Xijie, Sun Zhilei, Xu Yonghang, Li Yunhai, Shao Changwei. Measurement of sulfate reduction rate in coastal sediments of Jiulong River Estuary with a radiotracer technique[J]. Haiyang Xuebao, 2015, 37(4): 83-93. doi: 10.3969/j.issn.0253-4193.2015.04.008

Measurement of sulfate reduction rate in coastal sediments of Jiulong River Estuary with a radiotracer technique

doi: 10.3969/j.issn.0253-4193.2015.04.008
  • Received Date: 2014-03-31
  • Rev Recd Date: 2014-09-23
  • Sulfate reduction rates were measured experimentally with 35SO42- in sediment of A and B cores in coastal of Jiulong River Estuary in July of 2011. A and B cores were situated in the upper estuarine coast and seaward boundary respectively,with low salinity (3-5) and high salinity (20-25). Sulfate reduction rates volume-based values ranged from 54 to 2 345 nmol/(cm3·d) in vertical profile of A core,and the highest sulfate reduction rates occurred at 20 cm depth. Sulfate reduction rates varied from 24 to 987 nmol/(cm3·d) in B core,two peaks in sulfate reduction rates profiles obviously appeared on the top 10 cm and at 78cm depth,with significantly high value of 876 nmol/(cm3·d) and 987 nmol/(cm3·d),respectively. Based on trends on the vertical profile of SO42-,methane concentration in pore water and total organic carbon,temperature and oxidation reduction potential in sediments of two cores,sulfate reduction is mainly dominated by organic mineralization in A Core,however sulfate reduction is controlled by the combination of organic matter mineralization and anaerobic methane oxidation in B Core. Meanwhile sulfate reduction rates and the vertical distribution trends of it were affected by the availability of active organic matter,temperature and SO42- concentration in the pore water in two cores. The depth-integrated sulfate reduction rates were 527.9 mmol/(m2·d) and 357.1 mmol/(m2·d) within sulfate reduction zone in A Core and B Core respectively. Sulfate reduction is one of the major processes contributing to the mineralization of organic matter in this estuary.
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  • Vairavamurthy M A,Orr W L,Manowitz B. Geochemical transformation of sedimentary sulfur: an introduction[M]//Vairavamurthy M A,Schoonen M A A. Geochemical Tranformation of Sedimentary Sulfur. Washington,DC: ACS Symposium,1995: 1-17.
    Bottrell S H,Newton R J. Reconstruction of changes in global sulfur cycling from marine sulfate isotopes[J]. Earth-Science Reviews,2006,75(1/4): 59-83.
    JØrgensen B B. The sulfur cycle of coastal marine sediment (Limfjorden,Denmark)[J]. Limnology and Oceanography,1977,22(5): 814-832.
    Kallmeyer J,Ferdelman T G,Weber A,et al. A cold chromium distillation procedure for radio labeled sulfide applied to sulfate reduction measurements[J]. Limnology and Oceanography Methods,2004,2: 171-180.
    Fossing H,JØrgensen B B. Measurement of bacterial sulfate reduction in sediments: Evaluation of a single-step chromium reduction method[J]. Biogeochemistry,1989,8(3): 205-222.
    JØrgensen B B,Fenchel T. The sulfur cycle of a marine sediment model system[J]. Marine Biology,1974,24(3): 189-201.
    Sweeney R E,Kaplan I R. Diagenetic sulfate reduction in marine sediments[J]. Marine Chemistry,1980,9(3): 165-174.
    Berner R A. Sulfate reduction and the rate of deposition of marine sediments[J]. Earth and Planetary Science Letters,1978,37(3): 492-498.
    Bowles M W,Samarkin V A,Bowles K M,et al. Weak coupling between sulfate reduction and the anaerobic oxidation of methane in methane-rich seafloor sediments during ex situ incubation[J]. Geochimica et Cosmochimica Acta,2011,75(2): 500-519.
    Lee T,Hyun J H,Mok J S,et al. Organic carbon accumulation and sulfate reduction rates in slope and basin sediments of the Ulleung Basin,East/Japan Sea[J]. Geo-Marine Letters,2008,28(3): 153-159.
    Meister P,Liu B,Ferdelman T G,et al. Control of sulphate and methane distributions in marine sediments by organic matter reactivity[J]. Geochimica et Cosmochimica Acta,2013,104: 183-193.
    Al-Raei A M,Bosselmann K,Böttcher M E,et al. Seasonal dynamics of microbial sulfate reduction in temperate intertidal surface sediments: controls by temperature and organic matter[J]. Ocean Dynamics,2009,59(2): 351-370.
    Gribsholt B,Kristensen E. Benthic metabolism and sulfur cycling along an inundation gradient in a tidal Spartina anglica salt marsh[J]. Limnology and Oceanography,2003,48(6): 2151-2162.
    Thang N M,Brüchert V,Formolo M,et al. The impact of sediment and carbon fluxes on the biogeochemistry of methane and sulfur in Littoral Baltic Sea Sediments (Himmerfjrden,Sweden)[J]. Estuaries and Coasts,2013,36(1): 98-115.
    孙炳寅,经美德. 废黄河口盐沼土硫酸盐还原速率的研究[J]. 应用生态学报,1990,1(3): 248-253. Sun Bingyin, Jing Meide. A study on sulfate reduction in salt marsh near the estuary of obsolete Huanghe River[J]. Chinese Journal of Applied Ecology, 1990, 1(3):248-253.
    Wu Z J,Zhou H Y,Peng X T,et al. Rates of bacterial sulfate reduction and their response to experimental temperature changes in coastal sediments of Qi'ao Island,Zhujiang River Estuary in China[J]. Acta Oceanologica Sinica,2014,33(8): 10-17.
    程思海,陆红锋. 海洋沉积物孔隙水的制备方法[J]. 岩矿测试,2005,24(2): 102-104. Cheng Sihai, LU Hongfeng. Techniques for marine sediment pore-water sampling[J]. Rock and Mineral Analysis, 2005, 24(2):102-104.
    吴自军,周怀阳,彭晓彤,等. 甲烷厌氧氧化作用: 来自珠江口淇澳岛海岸带沉积物间隙水的地球化学证据[J]. 科学通报,2006,51(17): 2052-2059. Wu Zijun,Zhou Huaiyang,Peng Xiaotong,et al.Anaerobic oxidation of methane: Geochemical evidence from pore-water in coastal sediments of Qi'ao Island(Pearl River Estuary), southern China[J]. Chinese Science Bulletin, 2006, 51(17): 2052-2059.
    Schulz H D,Zabel M. Marine Geochemistry[M]. Berlin: Springer,2006: 198-199.
    张胜,张翠云,张云,等. 地质微生物地球化学作用的意义与展望[J]. 地质通报,2005,24(10/11): 1027-1031. Zhang Sheng, Zhang Cuiyun, Zhang Yun, et al. Geomicrobial geochemical processes: Significance and prospects[J]. Regional Geology of China, 2005, 24(10/11):1027-1031.
    Froelich P N,Klinkhammer G P,BenderM L,et al. Early oxidation of organic matter in pelagic sediments of the eastern equatorial Atlantic: Suboxic diagenesis[J]. Geochimica et Cosmochimica Acta,1979,43(7): 1075-1090.
    Canfield D E. Organic matter oxidation in marine sediments //Wollast R,Mackenzie F T,Chou L,et al. Interactions of C,N,P and S Biogeochemical Cycles and Global Change. Berlin Heidelberg: Springer-Verlag,1993: 333-363.
    Burdige D J. Geochemistry of Marine Sediments[M]. USA: Princeton University Press,2006.
    尹希杰,陈坚,郭莹莹,等. 九龙江河口沉积物中硫酸盐还原与甲烷厌氧氧化:同位素地球化学证据[J]. 海洋学报,2011,33(4): 121-128. Yin Xijie, Chen Jian, Guo Yingying, et al. Sulfate reduction and methane anaerobic oxidation: isotope geochemical evidence from the pore water of coastal sediments in the Jiulong Estuary[J]. Haiyang Xuebao, 2011,33(4),121-128.
    Wijsman J W M,Middelburg J J,Herman P M J,et al. Sulfur and iron speciation in surface sediments along the northwestern margin of the Black Sea[J]. Marine Chemistry,2001,74(4): 261-278.
    尹希杰,周怀阳,杨群慧,等. 珠江口淇澳岛海岸带沉积物中硫酸盐还原和不同形态硫的分布[J]. 海洋学报,2010,32(3): 31-39. Yin Xijie, Zhou Huaiyang, Yang Qunhui, et al. Sulfate reduction and reduced sulfur speciation in the coastal sediments of Qi'ao Island in the Zhujiang Estuary in China[J]. Haiyang Xuebao, 2010, 32(3):31-39.
    Marvin-DiPasquale M C,Boynton W R,Capone D G. Benthic sulfate reduction along the Chesapeake Bay central channel. Ⅱ. Temporal controls[J]. Marine Ecology Progress Series,2003,260: 55-70.
    Beck M,Dellwig O,Liebezeit G,et al. Spatial and seasonal variations of sulphate,dissolved organic carbon,and nutrients in deep pore waters of intertidal flat sediments[J]. Estuarine,Coast Shelf Science,2008,79(2): 307-316.
    Manous J J,Gantzer C J,Stefan H G. Spatial Variation of Sediment Sulfate Reduction Rates in a Saline Lake [J]. Journal of Environmental Engineering,2007,133(12): 1106-1116.
    Edenborn H M,Silverberg N,Mucci A,et al. Sulfate reduction in deep coastal marine sediments[J]. Marine Chemistry,1987,21(4): 329-345.
    Coleman M L,Raiswell R. Source of carbonate and origin of zonation in pyritiferous carbonate concretions: evaluation of a dynamic model[J]. American Journal of Science,1995,295(3): 282-308.
    Pallud C,Cappellen P V. Kinetics of microbial sulfate reduction in estuarine sediments[J]. Geochimica et Cosmochimica Acta,2006,70(5): 1148-1162.
    Schubert C S,Ferdelman T G,Strotmann B. Organic matter composition and sulfate reduction rates in sediments off Chile[J]. Organic Geochemistry,2000,31(5): 351-361.
    Canfield D E. Sulfate reduction in deep sea sediments[J]. American Journal of Science,1991,291(2): 177-188.
    Devol A H,Ahmend S I. Are high rates of sulphate reduction associated with anaerobic oxidation of methane? [J]. Nature,1981,291(5814): 407-408.
    Pohlman J W,Ruppel C,Hutchinson D R,et al. Assessing sulfate reduction and methane cycling in a high salinity pore water system in the northern Gulf of Mexico[J]. Marine and Petroleum Geology,2008,25(9): 942-951.
    Li Q Q,Wang F P,Chen Z W,et al. Stratified active archaeal communities in the sediments of Jiulong river estuary China[J]. Frontiers in Microbiology,2012,3: 311.
    Wenzhofer F,Glud R N. Benthic carbon mineralization in the Atlantic: a synthesis based on in situ data from the last decade[J]. Deep-Sea Research,2002,49(7): 1255-1279.
    Jahnke R A. The global ocean flux of particulate organic carbon: A real distribution and magnitude[J]. Global Biogeochemical Cycles,1996,10(1): 71-88.
    Hadas O. Sulfate reduction in Lake Agmon,Israel[J]. Science of the Total Environment,2001,266(1/3): 203-209.
    Julies E M,Fuchs B M,Arnosti C,et al. Organic carbon degradation in anoxic Organic-Rich shelf sediments: Biogeochemical rates and microbial abundance[J]. Geomicrobiology Journal,2010,27(4): 303-314.
    Sawicka1 J E,JØrgensen B B,Brüchert V. Temperature characteristics of bacterial sulfate reduction in continental shelf and slope sediments[J]. Biogeosciences,2012,9(8): 3425-3435.
    Weber A,JØrgensen B B. Bacterial sulfate reduction in hydrothermal sediments of the Guaymas Basin,Gulf of California,Mexico[J]. Deep-Sea Research I,2002,49(5): 827-841.
    Treude T,Niggemann J,Kallmeyer J,et al. Anaerobic oxidation of methane and sulfate reduction along the Chilean continental margin[J]. Geochimica et Cosmochimica Acta,2005,69(11): 2767-2779.
    Bertics V J,Ziebis W. Bioturbation and the role of microniches for sulfatereduction in coastal marine sediments[J]. Environmental Microbiology,2010,12(11): 3022-3034.
    Laverman A M,Pallud C,Abell J. et al. Comparative survey of potential nitrate and sulfate reduction rates in aquatic sediments[J]. Geochimica et Cosmochimica Acta,2012,77: 474-488.
    Hines M E,Knollmeyer S L,Tugel J B. Sulfate reduction and other sedimentary biogeochemistry in a northern New England salt marsh[J]. Limnology and Oceanography,1989,34(3): 578-590.
    Maltby E,Immirzi C P. Carbon dynamics in peatlands and other wetlands soils: regional and global perspectives[J]. Chemosphere,1993,27(6): 999-1023.
    Hyun J H,Smith A C,Kostka J E. Relative contributions of sulfate-and iron(III) reduction to organic matter minrtalization and process controls in contrasting habitats of the Georgia saltmarsh[J]. Applied Geochemistry,2007,22(12): 2637-2651.
    Thamdrup B. Bacterial manganese and iron reduction in aquatic sediments[J]. Advances in Microbiology and Ecology,2000,16: 41-84.
    Weber A,Riess W,Wenzhoefer F,et al. Sulfate reduction in Black Sea sediments: In situ and laboratory radiotracer measurements from the shelf to 2000 m depth[J]. Deep-Sea Research,2001,48(9): 2073-2096.
    Bruchert V,Gorgensen B B,Neumann K,et al. Regulation of bacterial sulfate reduction and hydrogen sulfide fluxes in the central Namibian coastal upwelling zone[J]. Geochimica et Cosmochimica Acta,2003,67(23): 4505-4518.
    Zopfi J,BöttcherM,JØrgensen B B. Biogeochemistry of sulfur and iron in Thioploca-colonized surface sediments in the upwelling area off central Chile[J]. Geochimica et Cosmochimica Acta,2008,72(3): 827-843.
    Devol A H,Anderson J J,Kuivila K,et al. A model for coupled sulfate reduction and methane oxidation in the sediments of Saanich Inlet[J]. Geochimica et Cosmochimica Acta,1984,48(5): 993-1004.
    Iversen N,JØrgensen B B. Anaerobic methane oxidation rates at the sulfate-methane transition in marine sediments from Kattegat and Skagerrak (Denmark)[J]. Limnology and Oceanography,1985,30(5): 944-955.
    Alperin M J,Reeburgh W S,Whiticar M J. Carbon and hydrogen isotope fractionation resulting from anaerobic methane oxidation[J]. Global Biogeochemical Cycles,1988,2(3): 279-288.
    Thode-Andersen S,JØrgensen B B. Sulfate reduction and the formation of 35S-labeled FeS,FeS2,and So in coastal marine sediments[J]. Limnology and Oceanography,1989,34(5): 793-806.
    JØrgensen B B,Bang M,Blackburn H T. Anaerobic mineralization in marine sediments from the Baltic Sea-North Sea transition[J]. Marine Ecology Progress Series,1990,59: 39-54.
    Oenema O. Sulfate reduction in fine-grained sediments in the Eastern Scheldt,southwest Netherlands[J]. Biogeochemistry,1990,9(1): 53-74.
    Roden E E,Tuttle J H. Inorganic sulfur cycling in mid and lower Chesapeake Bay sediments[J]. Marine Ecology Progress Series,1993,93: 101-118.
    Fossing H,Ferdelman T G,Berg P. Sulfate reduction and methane oxidation in continental margin sediments influenced by irrigation (South-East Atlantic off Namibia) [J]. Geochimica et Cosmochimica Acta,2000,64(5): 897-910.
    JØrgensen B B,Weber A,Zopfi J. Sulfate reduction and anaerobic methane oxidation in Black Sea sediments[J]. Deep-Sea Research,2001,48(9): 2097-2120.
    Mazumdar A,Paropkari A L,Borole D V,et al. Pore-water sulfate concentration profiles of sediment cores from Krishna-Godavari and Goa basins,India[J]. Geochemical Journal,2007,41: 259-269.
    Bowles M W,Samarkin V A,Bowles K M. Weak coupling between sulfate reduction and the anaerobic oxidation of methane in methane-rich seafloor sediments during ex situ incubation[J]. Geochimica et Cosmochimica Acta,2011,75(2): 500-519.
    Crill P M,Martens C S. Biogeochemical cycling in an organic-rich coastal marine basin. 6. Temporal and spatial variations in sulfate reduction rates[J]. Geochimica et Cosmochimica Acta,1987,51(5): 1175-1186.
    Takii S,Tanaka H,Kohata K,et al. Seasonal changes in sulfate reduction in sediments in the Inner Part of Tokyo Bay[J]. Microbes and Environments,2002,17(1): 10-17.
    Panutrakul S,Monteny F,Baeyens W,et al. Seasonal variations in sediment sulfur cycling in the Ballastplaat Mudflat,Belgium[J]. Estuaries,2001,24(2): 257-265.
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