异常海洋环境年份智利竹筴鱼捕捞效率的影响因素分析

为了探讨异常海洋环境年份智利竹筴鱼(Trachurus murphyi)捕捞效率及其相关影响因素,利用广义可加模型(GAM),对\"开富号\"2014年和2015年东南太平洋智利竹筴鱼的渔业生产统计数据进行分析研究。结果表明:(1)智利竹筴鱼的渔场主要位于26°S~28°S、74°W~76°W和37°S~47°S、78°W~93°W的海域内,其中最佳捕捞海域为38°S~47°S、87°W~93°W;最佳捕捞时间为4~6月;(2)放网的持续时间、月份、网口高度、网位、放网位置的经纬度及拖网速度对智利竹筴鱼捕捞效率的影响显著,而曳纲长度、网口水平扩张与智利竹筴鱼捕捞效率间的相关性则较弱;(3)影响智利竹筴鱼捕捞效率的因子按影响程度高低的顺序依次为放网的持续时间、月份、网口高度、放网经度、放网纬度、拖网速度、网位。     

Lateral migration of Arapaima gigas in floodplains of the Amazon

Abstract –  This study deduced in detail the lateral migration –those between river channels and floodplain habitats – of the pirarucu ( Arapaima gigas ), a giant, obligate air-breathing species of the Amazon Basin. Over a thousand samples of the pirarucu were taken through counts of the individuals performed at the moment of aerial breathing; these samples were taken in eight habitats of a floodplain near the Amazon River every week throughout an entire flood cycle. The lateral migration of the pirarucu accompanied water level fluctuations closely. As water levels rose, the pirarucu migrated to increasingly higher habitats in flooded forests and remained there during high water levels. As water levels declined, the pirarucu migrated first back to lower habitats of flooded forests, then to communicating channels, and, eventually, to the lakes, where they remained during low water levels. These results allow for a conceptual model of lateral migration of floodplain fishes.     

Variation in the population density of adult sea-trout, Salmo trutta, in 67 rivers in England and Wales

Abstract– Analysis of annual rod and commercial catches of adult seatrout demonstrated strong positive relationships between large-scale spatial variance (S²_s, variation in catches between rivers for each year) and spatial mean density (x?_s, mean catch per year), and also between temporal variance (S²_t, variation in catches between years for each river) and temporal mean density (x?_t, mean catch for each river). Both relationships were described by a power function, s²=ax^-b. For spatial variability, there were no significant differences between power functions for both rod and commercial catches from the North West, Welsh and South West regions. As the power b was not significantly different from two, relative spatial variability (measured by coefficients of variation (CV)) was fairly constant between years. Significantly higher values of b were obtained for the Wessex (GM b= 2.233) and North East (GM b=2.824) regions, and therefore the increase in CV with mean annual catch was significant but slight for Wessex rivers and marked for North East rivers. For temporal variability, there were no significant differences between power functions for both rod and commercial catches from all 5 regions and therefore a common power function was fitted to the data from all 67 rivers. As the power b was significantly less than two (GM b= 1.729), relative temporal variability (measured by CV) decreased significantly with increasing mean catch per river. Some limitations and implications of this analysis are discussed. Similar results from different regions for both rod and commercial catches suggest that such data do reflect adult population density, in spite of the different methods used to catch the sea-trout, variations in fishing effort and failures to report catches. The analysis of temporal variability provides a basis for classifying the major sea-trout rivers according to their mean annual catch and their relative variability in catches between years (using the CV).