Study on nutrient fluxes of sediment-water interface in cage culture zone of large yellow croaker Pseudosciaena crocea in Xiangshan Bay

  • LIAO Hong-fang ,
  • ZHENG Zhong-ming ,
  • REGAN Nicholaus ,
  • ZHU Jin-yong
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  • 1. School of Marine Sciences, Ningbo University, Ningbo 315211, China;
    2. The First Middle School of Linwu, Chenzhou 424300, China;
    3. Collaborative Innovation Center for Zhejiang Marine High-efficiency and Healthy Aquaculture, Ningbo 315211, China

Received date: 2014-11-05

  Revised date: 2015-12-08

  Online published: 2022-11-24

Abstract

Undisturbed sediment samples were collected from the cage culture zone and nearby of large yellow croaker' farm in Xiangshan Bay in May, Aug. and Nov. of 2013. Total organic nitrogen (TON), total organic carbon (TOC) and total phosphorus (TP) in the sediments were determined. A simulated experiment was conducted to study the sediment oxygen consumption (SOCs) rates and nutrients(NH+4、NO-2+NO-3、PO3-4) fluxes between water column and sediments. TON and TP values of sediment in cage-zone(YZ) are generally significantly higher than those in stations of 50 m away (F1) and 100 m away (F2) (P<0.05). The sediments release NH+4 to the overlying water where as they takes up NO-2+NO-3 and PO3-4. Benthic fluxes show that intensive seasonal variations and the release of NH+4and PO3- 4reach peak values in August, which response to increased organic input due to the yellow croaker farming. The nutrient concentration in water changes with benthic nutrient fluxes among seasons. The results obtained in this study imply that the ongoing aquaculture activities have led to sediment organic pollution at certain extent and the polluted sediment could affect the benthic nutrient fluxes, which might cause the redistribution of nutrients in water column.

Cite this article

LIAO Hong-fang , ZHENG Zhong-ming , REGAN Nicholaus , ZHU Jin-yong . Study on nutrient fluxes of sediment-water interface in cage culture zone of large yellow croaker Pseudosciaena crocea in Xiangshan Bay[J]. Journal of Marine Sciences, 2016 , 34(1) : 84 -92 . DOI: 10.3969/j.issn.1001-909X.2016.01.011

References

[1] BROOKS K M, MAHNKEN C V. Interactions of Atlantic salmon in the Pacific northwest environment: II Organic wastes [J]. Fisheries Research,2003,62(3):255-293.
[2] GRIGORAKIS K, RIGOS G. Aquaculture effects on environmental and public welfare-the case of Mediterranean mariculture [J]. Chemosphere,2011,85(6):899-919.
[3] KARAKASSIS I, TSAPAKIS M, HATZIYANNI E, et al. Impact of cage farming of fish on the seabed in three Mediterranean coastal areas [J]. ICES J Mar Sci: Journal du Conseil,2000,57(5):1 462-1 471.
[4] JIANG Zeng-jie, FANG Jian-guang, MAO Yu-ze, et al. Eutrophication assessment and bioremediation strategy in a marine fish cage culture area in Nansha Bay [J]. China Journal of Applied Phycology,2010,22(4):421-426.
[5] HUUSKONEN S E, RISTOLA T E, TUVIKENE A, et al. Comparison of two bioassays a fish liver cell line (PLHC-1) and a midge (Chironomus riparius), in monitoring freshwater sediments [J].Aquatic Toxicology,1998,44(1):47-67.
[6] HALLARE A V, SEILER T B, HOLLERT H. The versatile changing and advancing roles of fish in sediment toxicity assessment—a review [J]. Journal of Soils and Sediments,2011,11(1):141-173.
[7] HOLMER M, MARBA N, TERRADOS J, et al. Impacts of milkfish (Chanos chanos) aquaculture on carbon and nutrient fluxes in the Bolinao area Philippines [J]. Mar Pollut Bull,2002,44(7):685-696.
[8] YOKOYAMA H, ABO K, ISHIHI Y. Quantifying aquaculture-derived organic matter in the sediment in and around a coastal fish farm using stable carbon and nitrogen isotope ratios [J]. Aquaculture,2006,254(1):411-425.
[9] LAM K S, MACKAY D W, LAU T C, et al. Impact of marine fish farming on water quality and bottom sediment: a case study in the sub-tropical environment [J]. Marine Environmental Research,1994,38(2):115-145.
[10] MORATA T, SOSPEDRA J, FALCO S, et al. Exchange of nutrients and oxygen across the sediment-water interface below a Sparus aurata marine fish farm in the north-western Mediterranean Sea [J]. Journal of Soils and Sediments,2012,12(10)1 623-1 632.
[11] CAI Hui-wen, SUN Ying-lan, ZHANG Xue-qing. Environmental impact of cage aquaculture and aquaculture environmental capacity in Xiangshan harbor [J]. Techniques and Equipment for Environmental Pollution Control,2006,7(11):71-76.
蔡惠文,孙英兰,张学庆.象山港网箱养殖对海域环境的影响及其养殖环境容量研究[J].环境污染治理技术与设备,2006,7(11):71-76.
[12] QIU Qiong-fen, ZHANG De-min, YE Xian-sen, et al. The bacterial community of coastal sediments influenced by cage culture in Xiangshan Bay, Zhejiang, China[J]. Acta Ecologica Sinica,2013,33(2):483-491.
裘琼芬,张德民,叶仙森,等.象山港网箱养殖对近海沉积物细菌群落的影响[J].生态学报,2013,33(2):483-491.
[13] WANG You-shao, XU Ji-rong. A borderless disturbed sediment core sampler: China, CN1683915A[P].2004-10-19.
王友绍,徐继荣.一种无边界扰动的单管沉积物采样器:中国,CN1683915A[P].2004-10-19.
[14] ZHENG Zhong-ming, DONG Shuang-lin, TIAN Xiang-lin, et al. Sediment-water fluxes of nutrients and dissolved organic carbon in extensive sea cucumber culture ponds [J].Clean-Soil, Air, Water,2009,37(3):218-224.
[15] MUDROCH A, AZCUE J M, MUDROCH P. Manual of physico-chemical analysis of aquatic sediments[M]. Florida,USA: CRC Press,1995:123-124.
[16] BOYLE J. A comparison of two methods for estimating the organic matter content of sediments [J]. Journal of Paleolimnology,2004,31(1):125-127.
[17] CHICILEV S, IVANOV M. Response of the Arctic benthic community to excessive amounts of nontoxic organic matter [J]. Mar Pollut Bull,1997,35(7):280-286.
[18] CRANFORD P J, HARGRAVE B T, DOUCETTE L I. Benthic organic enrichment from suspended mussel (Mytilus edulis) culture in Prince Edward Island Canada [J]. Aquaculture,2009,292(3):189-196.
[19] WANG Li-sha, SHI Xiao-yong, ZHANG Chuan-song. Distribution and origins of organic carbon and organic nitrogen in ECS sediments of high-frequency HABs areas[J]. Marine Environmental Science,2010,29(2):165-169.
王丽莎,石晓勇,张传松.东海赤潮高发区沉积物中有机碳,有机氮的分布及其来源[J].海洋环境科学,2010,29(2):165-169.
[20] ZHANG Xue-lei, ZHU Ming-yuan, TANG Ting-yao, et al. Fluxes of nutrients at sediment-water in Sanggou Bay and Jiaozhou Bay in summer [J]. Marine Environmental Science,2004,23(1):1-4.
张学雷,朱明远,汤庭耀,等.桑沟湾和胶州湾夏季的沉积物-水界面营养盐通量研究[J].海洋环境科学,2004,23(1):1-4.
[21] ZHAI Bing. Distribution characteristics, influential factors and pollution sssessment of nitrogen and phosphorus in surface sediments of Xiangshan Bay[D]. Qingdao: Ocean University of China,2006.
翟滨.象山港表层沉积物中氮和磷的分布特征,影响因素及其污染评价[D].青岛:中国海洋大学,2006.
[22] DE VITTOR C, FAGANELI J, EMILI A, et al. Benthic fluxes of oxygen, carbon and nutrients in the Marano and Grado Lagoon (northern Adriatic Sea Italy) [J]. Estuarine Coastal and Shelf Science,2012,113:57-70.
[23] MANTZAVRAKOS E, KORNAROS M, LYBERATOS G, et al. Impacts of a marine fish farm in Argolikos Gulf (Greece) on the water column and the sediment [J]. Desalination,2007,210:110-124.
[24] J JØRGENSEN B B. Processes at the sediment-water interface[M]//BERT B, COOK R B. The major biogeochemical cycles and their interactions. SCOPE 21, Stockholm,1983:477-509.
[25] JENSEN M H, LOMSTEIN E, SØRENSEN J. Benthic NH4 and NO3 flux following sedimentation of a spring phytoplankton bloom in Aarhus Bight Denmark Mar [J]. Ecol Prog Ser,1990,61:87-96.
[26] AXLER R, TIKKANEN C, MCDONALD M, et al. Water quality issues associated with aquaculture: A case study in mine pit lakes [J]. Water Environ Res,1996,68(6):995-1 011.
[27] FERRÓN S, ORTEGA T, FORJA J M. Benthic fluxes in a tidal salt marsh creek affected by fish farm activities: Río San Pedro (Bay of Cádiz SW Spain) [J]. Marine Chemistry,2009,113(1):50-62.
[28] SUN San, LI Jia-hui, JIN Yang, et al. Distribution features of nutrients and flux between the sediment and water interface in Sishili bay[J].Marine Environmental Sicence,2012,31(2):195-200.
孙珊,李佳蕙,靳洋,等.烟台四十里湾海域营养盐和沉积物-水界面交换通量[J].海洋环境科学,2012,31(2):195-200.
[29] CANFIELD D E, JØGENSEN B B, FOSSING H, et al. Pathways of organic carbon oxidation in three continental margin sediments[J]. Marine Geology,1993,113(1-2):27-40.
[30] CLINE J D, RICHARDS F A. Oxygen deficient conditions and nitrate reduction in the eastern tropical North Pacific Ocean [J]. Limnol Oceanogr,1972,17(6):885-900.
[31] MURRAY J W, CODISPOTI L A, FRIEDERICH G E. Oxidation-reduction environments: the suboxic zone in the Black Sea [J]. ACS Advances in Chemistry Series,1995,244:157-176.
[32] BOON P I, MORIARTY D J W, SAFFIGNA P G. Rates of ammonium turnover and the role of amino-acid deamination in seagrass (Zostera capricorni) beds of Moreton Bay Australia [J]. Marine Biology,1986,91(2):259-268.
[33] GARDNER W S, MCCARTHY M J, AN S. Nitrogen fixation and dissimilatory nitrate reduction to ammonium (DNRA) support nitrogen dynamics in Texas estuaries [J]. Limnology and Oceanography,2006,51(1):558-568.
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