莱州湾芙蓉岛人工鱼礁区生态系统能量流动及仿刺参生态容量评估

丁夏阳; 孙昕; 董建宇; 詹启鹏; 张宗航; 张镇; 申丰源; 张沛东; 张秀梅

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莱州湾芙蓉岛人工鱼礁区生态系统能量流动及仿刺参生态容量评估
丁夏阳,孙昕,董建宇,詹启鹏,张宗航,张镇,申丰源,张沛东,张秀梅
1.中国海洋大学海水养殖教育部重点实验室山东青岛 266003;2.浙江海洋大学水产学院浙江舟山 316022;3.青岛海洋科学与技术试点国家实验室海洋渔业科学与食物产出过程功能实验室山东青岛 266237

摘要:

基于2019年莱州湾芙蓉岛人工鱼礁区渔业资源调查数据，利用Ecopath with Ecosim 6.6 (EwE 6.6)软件构建了芙蓉岛人工鱼礁区生态系统Ecopath模型，系统分析了芙蓉岛人工鱼礁区生态系统的能量流动规律和结构特征，估算了仿刺参(Apostichopus japonicus)的生态容量。Ecopath模型由16个功能组组成，基本涵盖了芙蓉岛人工鱼礁区生态系统能量流动的主要过程。结果发现，生态系统各功能组的营养级范围为1.000~3.978，其中，花鲈(Lateolabrax maculatus)处于最高营养级；生态系统总转换效率为10.6%，来自初级生产者的转换效率为10.8%，来自碎屑的转换效率为10.1%；生态系统总流量为2 596.108 t/(km2·a)，其中44%来自碎屑；系统总初级生产量/总呼吸量为1.454，连接指数为0.402，系统杂食指数为0.211，Finn´s循环指数和平均路径长度分别为8.860%和2.980。结果表明，芙蓉岛人工鱼礁区生态系统成熟度和稳定性较低，食物网结构较简单。根据模型计算得出，仿刺参的生态容量为131 t/km2，是现存量的6.55倍，具有较大的增殖潜力。

关键词: 芙蓉岛人工鱼礁 Ecopath模型生态容量

DOI：10.19663/j.issn2095-9869.20210924001

分类号:

基金项目:

Assessment of ecosystem energy flow and ecological capacity of Apostichopus japonicus in the Furong Island artificial reef, Laizhou Bay

DING Xiayang^1,2, SUN Xin^1,2, DONG Jianyu^1,2, ZHAN Qipeng^1,2, ZHANG Zonghang^1,2, ZHANG Zhen^1,2, SHEN Fengyuan^1,2, ZHANG Peidong^1,2, ZHANG Xiumei^3,4

1.Key Laboratory of Mariculture, Ministry of Education;2.Ocean University of China, Qingdao, Shandong 266003, China;3.School of Fishery, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China;4.Laboratory for Marine Fisheries Science and Food Production Processes, Pilot National Laboratory for Marine Science and Technology (Qingdao), Qingdao, Shandong 266237, China

Abstract:

The fishery resources in the Furong Island, Laizhou Bay artificial reef were investigated in 2019; the energy flows and structure of the ecosystem were modeled, and the ecological capacity of Apostichopus japonicus was estimated using an Ecopath with Ecosim 6.6 (EwE 6.6). The model included 16 functional groups that covered the main processes of energy flows in the Furong Island artificial reef ecosystem. According to the results, the trophic levels of the functional groups varied from 1.000 to 3.978; Lateolabrax maculatus occupied the highest trophic level. The total transfer efficiency was 10.6%, and the proportions of the total flow originating from primary producers and detritus were 10.8% and 10.1%, respectively. The total system throughput was estimated to be 2 596.108 t/(km2·a), with 44% originating from detritus. The ratio between the total primary productivity and the total respiration of the system was 1.454; the connectance index was 0.402; the system omnivory index was 0.211; and the Finn cycling index and Finn mean path length were 8.860% and 2.980, respectively. The results showed that the Furong Island artificial reef ecosystem was at a relatively low maturity and stability level with a relatively simple food web. The ecological capacity of A. japonicus estimated by the model was 131 t/km2, which is 6.55 times the existing stock, indicating its growth potential. According to the actual production situation, the ecological balance of the ecosystem can be maintained with an annual catch of 4.1 t/km2. At present, there are few studies using the Ecopath model to evaluate the ecological consequences or ecological capacities of artificial reefs, in China or abroad, and there is little discussion about fishery management models. More applications and verification on artificial reefs are required. This study is expected to provide a scientific basis for the evaluation of ecological consequences of artificial areas and the sustainable utilization of marine ranches.

Key words: Furong Island Artificial reef Ecopath model Ecological capacity