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| 深远海大型围栏养殖大黄鱼海域沉积物质量分析与评价 |
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宋炜1,2,3, 陈志和1,2, 谢正丽4, 刘永利1, 王磊1, 王鲁民1
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1.中国水产科学研究院东海水产研究所 上海 200090;2.南昌大学生命科学学院
江西 南昌 330031;3.青岛海洋科学与技术试点国家实验室 山东 青岛 266237;4.中国水产科学研究院渔业机械仪器研究所 上海 200092
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| 摘要: |
| 为评价深远海大型围栏养殖大黄鱼(Larimichthys crocea)海域的沉积物质量状况,通过对大黄鱼不同养殖期围栏养殖区、围栏外围区、网箱外围区和对照区的4次调查,分析评价了调查海域沉积物中的Cu、Zn、有机碳、硫化物等指标的区域分布、含量变化及污染水平,并采用内梅罗指数对调查海域沉积物进行了质量综合评价。结果显示,4次调查大黄鱼围栏养殖区沉积物Cu的含量范围为15~33 mg/kg,Zn的含量范围为80~137 mg/kg,有机碳的含量范围为0.14%~1.90%,硫化物的含量范围为0.3~128.0 mg/kg。围栏中心区沉积物有机碳、硫化物的含量比其他区域高,但均符合《海洋沉积物质量》(GB18668-2002)中的一类标准。不同调查区域沉积物Cu、Zn和有机碳的含量差异不显著(P>0.05),围栏中心养殖区沉积物硫化物含量显著高于对照区(P<0.05)。内梅罗综合评价结果表明,调查区域沉积物质量均为清洁或较清洁状态,沉积物质量符合海水养殖标准。沉积物Cu、Zn和硫化物未表现出明显的累积趋势,沉积物有机碳在本调查时间内有轻微累积的趋势,建议通过加强大黄鱼配合饲料的研发与应用,以缓解目前冰鲜鱼饵料大规模投入的状况,降低饵料系数,从而在一定水平上减轻有机质累积对沉积环境的污染。 |
| 关键词: 深远海 围栏 大黄鱼 沉积物质量 |
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| Analysis and evaluation of sediment quality in a Larimichthys crocea farm cultured with a deep-sea large-scale fence |
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SONG Wei1,2,3, CHEN Zhihe1,2, XIE Zhengli4, LIU Yongli1, WANG Lei1, WANG Lumin1
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1.East China Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, Shanghai 200090, China;2.School of Life Sciences, Nanchang University, Nanchang, Jiangxi 330031, China;3.Pilot National Laboratory for Marine Science and Technology (Qingdao), Qingdao, Shangdong 266237, China;4.Fishery Machinery and Instrument Research Institute, Chinese Academy of Fishery Sciences, Shanghai 200092, China
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| Abstract: |
| Far-reaching mariculture is an important way to relieve the pressure on the ecological environment of coastal waters, expand new space for mariculture in China, optimize the layout of the marine fishery industry, and promote the green and high-quality development of aquaculture. In recent years, moving the islands and reefs far away from the continental coastline as the early development sea area and the equipment-first behavior as the development characteristics of deep-sea aquaculture, China´s far-reaching mariculture has been preliminarily developed. Combined with China´s sea areas, sea conditions, breeding varieties, and market demand, the independent and innovative large-scale engineering fence facility breeding model of Pseudosciaena crocea has been successful. In order to evaluate the sediment status in the sea area of the large-scale fenced large yellow croaker (Larimichthys crocea) in the deep-sea, the regional distribution, content change, and pollution level of Cu, Zn, organic carbon, sulfide and other indicators in the sediments of the surveyed sea area were analyzed. These parameters were evaluated through four investigations in the fenced culture area, peripheral area of the fence, peripheral area of the cage, and control area of L. crocea, in different culture periods, and the Nemerow index was used to comprehensively evaluate the quality of sediments in the surveyed sea area. The results showed that the Cu content in the sediments varied from 15~33 mg/kg; the Zn content varied from 80~137 mg/kg; the organic carbon content varied from 0.14%~1.90%; and the sulfide content varied from 0.3~128.0 mg/kg. The contents of organic carbon and sulfide in the sediments in the fenced culture area were higher than those in other areas, however, they all met the first class of marine sediment quality standards (GB18668-2002). There was no significant difference in the contents of Cu, Zn, and organic carbon in the sediments of the different investigation areas (P>0.05), and the content of sulfide in the sediments of the breeding area in the fence center was significantly higher than that in the control area (P<0.05). In this study, the Nemerow index comprehensive analysis revealed that the sediment quality of all sampling stations during the survey was of clean (classⅠ) or relatively clean (classⅡ) status, and the sediment quality of each station maintained a stable and good level during the survey time. On one hand, high breeding density is not an issue in the sea area, and the breeding layout is more scientific and reasonable, but good water exchange in the sea area can dilute and diffuse some pollutants, such as residual bait and feces; on the other hand, the deep-water network in the sea area generally occurs around December every year. Therefore, the large yellow croaker cultured in boxes and fences could be caught and sold. The large yellow croaker species can be re-invested around May of the next year. Thus, the sea area has several months for renewal of its resources in the non-breeding period. No obvious accumulation trend of Cu, Zn, and sulfide in the sediments was observed, but a slight accumulation trend of organic carbon in the sediments was observed during the study period. The research and development, and application of formula feed for the large yellow croaker should be enhanced to alleviate the current large-scale investment of frozen fish bait and reduce the bait coefficient, thus reducing the pollution of organic matter accumulation in the sedimentary environment to a certain extent. According to the breeding cycle of large-scale fenced L. crocea in the far-reaching sea, this study monitors the key characteristics and sedimentary environmental factors in the fenced breeding area and the surrounding sea areas. It comprehensively evaluates the current situation of sediment quality in order to have a basic understanding of the current situation of pollutants in large-scale fenced breeding. The results provide a basis for rational planning of the large-scale fenced breeding areas in the far-reaching sea and provide data support for disease control and sustainable development of mariculture. |
| Key words: Deep-sea Fence Larimichthys crocea Sediment quality |
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