Page 148 - 《水产学报》2026年第04期
P. 148
4 期 水 产 学 报 50 卷
[27] 夏锴铭. 浙江海域三疣梭子蟹早期生活史阶段海表温度对其 input change and response of the estuarine ecological environ-
后期产量的影响研究 [D]. 舟山: 浙江海洋大学, 2024. ment[D]. Qingdao: Institute of Oceanology, CAS, 2013 (in
Xia K M. Effect of sea surfer temperature during the early life Chinese).
history stages of Portunus trituberculatus on later yield in [35] Yue L T, Wang Y B, Xian W W, et al. Genetic diversity and
Zhejiang sea areas[D]. Zhoushan: Zhejiang Ocean University, population structure of Portunustrituberculatus in released and
2024 (in Chinese). wild populations based on microsatellite DNA markers from the
[28] 丁朋朋, 高春霞, 田思泉, 等. 浙江南部近海蟹类群落结构及 Yangtze Estuary[J]. Diversity, 2022, 14(5): 374.
其与环境因子的关系 [J]. 海洋渔业, 2019, 41(6): 652-662. [36] Sepulveda A J, Schabacker J, Smith S, et al. Improved detec-
Ding P P, Gao C X, Tian S Q, et al. Crab community structure tion of rare, endangered and invasive trout in using a new large
and its relationship with environment factors in the offshore ‐ volume sampling method for eDNA capture[J]. Environ-
waters of southern Zhejiang Province[J]. Marine Fisheries, mental DNA, 2019, 1(3): 227-237.
2019, 41(6): 652-662 (in Chinese). [37] Strickler K M, Fremier A K, Goldberg C S. Quantifying effects
[29] Kasai A, Takada S, Yamazaki A, et al. The effect of temperat- of UV-B, temperature, and pH on eDNA degradation in aquatic
ure on environmental DNA degradation of Japanese eel[J]. microcosms[J]. Biological Conservation, 2015, 183: 85-92.
Fisheries Science, 2020, 86(3): 465-471. [38] de Sousa L L, Silva S M, Xavier R. DNA metabarcoding in diet
[30] 颜文超. 浙江渔场三疣梭子蟹渔获量波动与人类干扰和环境 studies: unveiling ecological aspects in aquatic and terrestrial
因子的关系研究 [D]. 舟山: 浙江海洋大学, 2019. ecosystems[J]. Environmental DNA, 2019, 1(3): 199-214.
Yan W C. Study on the relationship between the catch fluctu- [39] McCartin L J, Vohsen S A, Ambrose S W, et al. Temperature
ation of Portunus trituberculatus and the human disturbance controls eDNA persistence across physicochemical conditions
and environment factors in Zhejiang fishery[D]. Zhoushan: in seawater[J]. Environmental Science & Technology, 2022,
Zhejiang Ocean University, 2019 (in Chinese). 56(12): 8629-8639.
[31] 卢衎尔, 张洪亮, 朱文斌, 等. 浙江近海春、夏季蟹类群落结 [40] El-Bokhty E A E B, El-Ganainy A A, Khalil M T, et al. Effect
构及其与环境因子的关系 [J]. 水生生物学报, 2019, 43(3): of diel variation on trawl fishery-catch rates in the Gulf of Suez,
612-622. Red Sea, Egypt[J]. Egyptian Journal of Aquatic Biology &
Lu K E, Zhang H L, Zhu W B, et al. Community structure of Fisheries, 2021, 25(6): 503-512.
crabs and its relationship with environmental factors in Zheji- [41] Somerton D A, Weinberg K L, Goodman S E. Catchability of
ang coast area in spring and summer[J]. Acta Hydrobiologica snow crab (Chionoecetes opilio) by the eastern Bering Sea bot-
Sinica, 2019, 43(3): 612-622 (in Chinese). tom trawl survey estimated using a catch comparison experi-
[32] Lu H J, Lee H L. Changes in the fish species composition in the ment[J]. Canadian Journal of Fisheries and Aquatic Sciences,
coastal zones of the Kuroshio Current and China Coastal Cur- 2013, 70(12): 1699-1708.
rent during periods of climate change: observations from the set- [42] Jiang H D, Ye Z J, Zhang Y X, et al. The integration of diel
net fishery (1993-2011)[J]. Fisheries Research, 2014, 155: 103- vertical migration and hydrodynamic process influences the
113. transport of swimming crab zoea (Portunus trituberculatus)[J].
[33] Anger K. The biology of decapod crustacean larvae[M]. Lisse Fisheries Oceanography, 2025, 34(1): e12695.
Exton: A. A. Balkema Publishers, 2001. [43] Urban P, Bekkevold D, Degel H, et al. Scaling from eDNA to
[34] 梁翠. 长江口陆源输入变化及河口生态环境响应的初步研究 biomass: controlling allometric relationships improves preci-
[D]. 青岛: 中国科学院研究生院 (海洋研究所), 2013. sion in bycatch estimation[J]. ICES Journal of Marine Science,
Liang C. A preliminary study of the Yangtze River terrestrial 2023, 80(4): 1066-1078.
https://www.china-fishery.cn 中国水产学会主办 sponsored by China Society of Fisheries
10
