Abstract
Many studies have revealed that anchovy has exhibited large variability in population size on decadal timescales. However, such works concerning anchovy population are mainly based on short historical catch records. In order to understand the causes of variability in fish stocks (natural and/or anthropogenic) and calibrate the error between catches and standing stocks, it is essential to develop long-term time series of fish stocks from the time when human impacts are minimal or negligible. Well preserved fish scales from sediment record are regarded as useful indicators revealing the history of fish population dynamics over the last centuries. Anchovy scales was first analyzed over the Yellow Sea and East China Sea and the largest abundance was found in the central South Yellow Sea where is regarded as the largest overwintering ground for Japanese anchovy (Engraulis japonicas). Thus in the central South Yellow Sea, two cores covering the last 150 years were collected for estimating fish scale flux. The scale deposition rate (SDR) records show that the decadal scale SDRs were obviously coherent between cores with independent chronologies. The calibration of downcore SDRs to the standing stocks of anchovy further validated that SDR is a reliable proxy to reconstruct the long-term anchovy population dynamic in the central South Yellow Sea where anoxic conditions prevail in the sediment. When assembled with other productivity proxies, it would be expected that SDR could be associated with changes in oceanic productivity and may make a contribution to determine the forcing factors and elucidate the mechanism of the process in future.
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References
Baumgartner T, Soutar A, Ferreira-Bartrina V. 1992. Reconstruction of the history of Pacific sardine and northern anchovy populations over the past two millennia from sediments of the Santa Barbara Basin, California. CalCOFI Reports, 33: 24–40
Díaz-Ochoa J, Lange C, Pantoja S, et al. 2009. Fish scales in sediments from off Callao, central Peru. Deep-Sea Research Part II, 56(16): 1124–1135
DeVries T J. 1979. Nekton remains, diatoms, and Holocene upwelling off Peru [dissertation]. Oregon, USA: Oregon State University
DeVries T J, Pearcy W G. 1982. Fish debris in sediments of the upwelling zone off central Peru: a late Quaternary record. Deep-Sea Research Part I, 29(1): 87–109
Drago T, Ferreira-Bartrina V, Santos A, et al. 2009. The use of fish remains in sediments for the reconstruction of paleoproductivity. IOP Conference Series: Earth and Environmental Science, 5(1): 1–10
Finney B P, Alheit J, Emeis K C, et al. 2010. Paleoecological studies on variability in marine fish populations: a long-term perspective on the impacts of climatic change on marine ecosystems. Journal of Marine Systems, 79(3–4): 316–326
Francis R C, Hare S R. 1994. Decadal-scale regime shifts in the large marine ecosystems of the north-east Pacific: A case for historical science. Fisheries Oceanography, 3(4): 279–291
Gallardo A. 1963. Notas sobre la densidad de la fauna bentónica en el sublitoral del norte de Chile. Gayana Zoologia (in Spanish), 10: 1–15
Holmgren D. 2001. Decadal-centennial variability in marine ecosystems of the Northeast Pacific Ocean: the use of fish scales depositions in sediments [dissertation]. Washington, USA: University of Washington
Ichikawa H, Beardsley R C. 2002. The current system in the Yellow and East China Seas. Journal of Oceanography, 58(1): 77–92
Jia Haibo, Sun Yao, Zhao Meixun, et al. 2008. Fish scale-deposition information and spatial distribution in typical fishery area of the Yellow Sea and East China Sea. Journal of Fisheries of China (in Chinese), 32(4): 584–591
Jin Xianshi, Johannes H, Zhao Xianyong, et al. 2001. Study on the quota management of anchovy (Engraulis japonicus) in the Yellow Sea. Journal of Fisheries of China (in Chinese), 8(3): 27–30
Kirchner G. 2011. 210Pb as a tool for establishing sediment chronologies: examples of potentials and limitations of conventional dating models. Journal of Environmental Radioactivity, 102(5): 490–494
Li Fengye, Gao Shu, Jia Jianjun, et al. 2002. Contemporary deposition rates of fine grained sediment in the Bohai and Yellow seas. Oceanologia et Limnologia Sinica (in Chinese), 33(4): 364–369
Li Fengye, Yang Yongliang, He Lijuan, et al. 1999. Discussion on sedimentation rates and material source in the east part of the south Yellow Sea. Marine Sciences (in Chinese), (5): 37–40
Li Yao, Zhao Xianyong, Zheng Tao, et al. 2007. Wintering migration and distribution of anchovy in the Yellow Sea and its relation to physical environment. Marine Fisheries Research (in Chinese), 28(2): 104–112
Liu Xiqing. 1996. Sedimentary division in marginal seas of China. Marine Geology & Quaternary Geology (in Chinese), 16(3): 1–11
Liu J P, Mlilliman J D, Gao Shu, et al. 2004. Holocene development of the Yellow River’s subaqueous delta, North Yellow Sea. Marine Geol ogy, 209(1–4): 45–67
Liu Jian, Saito Y, Kong Xianghuai, et al. 2010. Delta development and channel incision during marine isotope stages 3 and 2 in the western South Yellow Sea. Marine Geology, 278(1–4): 54–76
Milessi A C, Sellanes J, Gallardo V I A, et al. 2005. Osseous skeletal material and fish scales in marine sediments under the oxygen minimum zone off northern and central Chile. Estuarine, Coastal and Shelf Science, 64(2–3): 185–190
Murphy G I. 1966. Population biology of the Pacific sardine (Sardinops caerulea). Proceeding of the California Academy of Science, 34(1): 1–84
Ñiquen M, Bouchon M. 2004. Impact of El Niño events on pelagic fisheries in Peruvian waters. Deep-Sea Research Part II, 51(6–9): 563–574
O’connell J M, Tunnicliffe V. 2001. The use of sedimentary fish remains for interpretation of long-term fish population fluctuations. Marine Geology, 174(1–4): 177–195
Patterson R T, Wright C, Chang A S, et al. 2002. Atlas of common squamatological (fish scale) material in coastal British Columbia and an assessment of the utility of various scale types in paleofisheries reconstruction. Palaeontologia Electronica, 4(1): 1–88
Salvatteci R, Field D B, Baumgartner T, et al. 2012. Evaluating fish scale preservation in sediment records from the oxygen minimum zone off Peru. Paleobiology, 38(1): 52–78
Schenau S J, Slomp C P, De Lange G J. 2000. Phosphogenesis and active phosphorite formation in sediments from the Arabian Sea oxygen minimum zone. Marine Geology, 169(1–2): 1–20
Schwartzlose R A, Alheit J, Bakun A, et al. 1999. Worldwide large-scale fluctuations of sardine and anchovy populations. South African Journal of Marine Science, 21(1): 289–347
Shi Xuefa, Shen Shunxi, Yi Hi-il, et al. 2003. Modern sedimentary environments and dynamic depositional systems in the southern Yellow Sea. Chinese Science Bulletin, 48(S1): 1–7
Soutar A. 1967. The accumulation of fish debris in cetain California Costal sediments. California. CalCOFI Reports, 11: 136–139
Soutar A, Isaacs J D. 1974. Abundance of pelagic fish during the 19th and 20th centuries as recorded in anaerobic sediment off the Californias. Fishery Bulletin, 72(2): 257–273
Valdés J, Ortlieb L, Gutierrez D, et al. 2008. 250 years of sardine and anchovy scale deposition record in Mejillones Bay, northern Chile. Progress in Oceanography, 79(2–4): 198–207
Wallin O. 1957. On the growth structure and developmental physiology of the scale of fishes. Reports of the Institute of Fresh-water Research, Drottningholm, 38: 385–477
Wright C A, Dallimore A, Thomson R E, et al. 2005. Late Holocene paleofish populations in Effingham Inlet, British Columbia, Canada. Palaeogeography, Palaeoclimatology, Palaeoecology, 224(4): 367–384
Zhao Xianyong. 2006. Population dynamic characteristics and sustainable utilization of the anchovy stock in the Yellow Sea (in Chinese) [dissertation]. Qingdao, China: Ocean University of China
Zhao Xianyong, Chen Yuzhen, Li Xiansen, et al. 2003. Acoustic estimation of multi-species marine fishery resources. Acta Oceanologica Sinica (in Chinese), 25(1): 192–202
Zhao Yiyang, Li Fengye, DeMaster D J, et al. 1991. Preliminary studies on sedimentation rate and sediment flux of the south Huanghai Sea. Oceanologia et Limnologia Sinica (in Chinese), 22(1): 38–43
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Foundation item: The National Basic Research Program of China under contract Nos 2010CB428902 and 2006CB400007; the National Natural Science Foundation of China under contract No. 40876088.
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Huang, J., Sun, Y., Jia, H. et al. Spatial distribution and reconstruction potential of Japanese anchovy (Engraulis japonicus) based on scale deposition records in recent anaerobic sediment of the Yellow Sea and East China Sea. Acta Oceanol. Sin. 33, 138–144 (2014). https://doi.org/10.1007/s13131-014-0573-8
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DOI: https://doi.org/10.1007/s13131-014-0573-8