烟台养马岛养殖区营养盐时空分布特征及影响因素

doi:10.16378/j.cnki.1003-1111.25124

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摘要为了解烟台半封闭海湾——养马岛养殖区(N 37.5°~37.7°,E 121.5°~121.9°)的营养盐状况及对贝类养殖的影响,于2019—2024年8月(夏季),按照近岸密、远岸疏的原则,结合筏式养殖区站位可达性,网格化布设了43个站位,水深10~18 m,连续监测了烟台养马岛养殖区表层海水溶解无机氮(DIN)、活性磷酸盐(PO₄-P)和硅酸盐(SiO₃-Si)的浓度变化、平面分布和限制特征。监测结果显示:养马岛养殖区溶解无机氮平均浓度为(7.92±5.79) μmol/L,时间上浓度持续下降,空间上呈近岸向远海逐渐降低的平面分布;活性磷酸盐平均浓度为(0.174±0.130) μmol/L,时间上浓度持续下降,空间上呈中间低、四周高的平面分布,养殖区中间形成“中心凹陷型”匮乏区;硅酸盐平均浓度为(11.60±3.58) μmol/L,时间上浓度先升后降,空间上呈近岸向远海逐渐降低的平面分布。营养盐结构呈明显的活性磷酸盐限制,N/P和Si/P中位数分别为43.6和79.5,高值区主要位于养殖区中间区域。陆源营养盐输入锐减和长牡蛎高密度养殖快速增加,共同构成营养盐持续下降和磷循环失衡的双重驱动机制,并通过多路径胁迫牡蛎生理功能,造成贝类肥满度低、死亡率升高。研究结果表明,合理调控养殖密度和科学量化氮磷减排比例,对改善养殖区生态环境和保障海水养殖业的可持续发展具有重要意义。

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关键词 ：养马岛, 水产养殖, 营养盐, 分布特征, 影响因素

Abstract：To understand status and impact of the nutrient on shellfish culture in the aquaculture area at Yangma Island(N 37.5°—37.7°,E 121.5°—121.9°)(semi-enclosed bay), Yantai, Shandong province, the concentration changes, spatial distribution, and limitation characteristics of dissolved inorganic nitrogen (DIN), reactive phosphate (PO₄-P), and silicate (SiO₃-Si) were analyzed in the seawater at 43 stations arranged in a grid, with a water depth of 10—18 m at this area in summer cruises in August from 2019 to 2024, in accordance with the sites-sampling principle of near-shore density and far-shore sparseness, and combined with the accessibility of raft breeding areas. The results showed that there was the average DIN concentration of (7.92±5.79) μmol/L, with continuous decrease and spatial distribution pattern of gradual decrease from the nearshore to the offshore areas. The average concentration of PO₄-P was found to be (0.174±0.130) μmol/L, continuous decrease and a spatial distribution pattern of lower values in the central area and high values around the periphery, thus forming a "central depression" deficiency zone in the middle of the aquaculture area. The average SiO₃-Si concentration of (11.60±3.58) μmol/L was decreased gradually from the nearshore to the offshore areas. The nutrient structure was characterized by a significant PO₄-P limitation, with median values of N/P ratio of 43.6 and Si/P ratio of 79.5, and the high-value zones primarily located in the central area of the aquaculture zone. Sharp declines in terrigenous nutrient inputs, and coupled with a rapid expansion of high-density farming of Pacific oysters Crassostrea gigas led to persistent nutrient depletion and a concomitant imbalance in phosphorus cycling. This dual mechanism imposes multi-pathway stress on oyster physiology, leading to reduce condition factor and to elevate mortality. The findings indicate that rational stocking-density control and scientifically quantified reductions in nitrogen and phosphorus discharge are essential for restoring the ecological integrity of aquaculture zones and for ensuring the sustainable development of mariculture.

Key words： Yangma Island aquaculture nutrient distribution characteristics impact factor

收稿日期: 2025-05-17

PACS:

X52

基金资助:烟台市科技创新发展计划项目(2024JCYJ072);烟台市级统筹涉农科研项目(202402).

通讯作者: 张山(1984—),女,硕士;研究方向:渔业环境监测. E-mail:20747753@qq.com.

作者简介: 王磊(1985—),男,高级工程师,硕士;研究方向:渔业环境监测. E-mail:269077781@qq.com.

引用本文:

王磊,迟守峰,王文君,李峰,汪顺周,张山. 烟台养马岛养殖区营养盐时空分布特征及影响因素[J]. 水产科学, 2026, 45(2): 227-238.
WANG Lei, CHI Shoufeng, WANG Wenjun, LI Feng, WANG Shunzhou, ZHANG Shan. Spatiotemporal Distribution Characteristics and Influencing Factors of Nutrients in Aquaculture Area at Yangma Island. Fisheries Science, 2026, 45(2): 227-238.

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https://www.shchkx.com/CN/10.16378/j.cnki.1003-1111.25124 或 https://www.shchkx.com/CN/Y2026/V45/I2/227

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