Assessing contributions of cold-water refuges to reproductive migration corridor conditions for adult Chinook Salmon and steelhead trout in the Columbia River, USA.

IF 4.6 Q2 ENVIRONMENTAL SCIENCES
Marcía N Snyder, Nathan H Schumaker, Jason B Dunham, Matthew L Keefer, Peter Leinenbach, Allen Brookes, John Palmer, Jennifer Wu, Druscilla Keenan, Joseph L Ebersole
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引用次数: 11

Abstract

Diadromous fish populations face multiple challenges along their migratory routes. These challenges include suboptimal water quality, harvest, and barriers to longitudinal and lateral connectivity. Interactions among factors influencing migration success make it challenging to assess management options for improving migratory fish conditions along riverine migration corridors. We describe a spatially explicit simulation model that integrates complex individual behaviors of fall-run Chinook Salmon (Oncorhynchus tshawytscha) and summer-run steelhead trout (O. mykiss) during migration, responds to variable habitat conditions over a large extent of the Columbia River, and links migration corridor conditions to fish condition outcomes. The model is built around a mechanistic behavioral decision tree that drives individual interactions of fish within their simulated environments. By simulating several thermalscapes with alternative scenarios of thermal refuge availability, we examined how behavioral thermoregulation in cold-water refuges influenced migrating fish conditions. Outcomes of the migration corridor simulation model show that cold-water refuges can provide relief from exposure to high water temperatures, but do not substantially contribute to energy conservation by migrating adults. Simulated cooling of the Columbia River decreased reliance on cold-water refuges and there were slight reductions in migratory energy expenditure. This modeling of simulated thermalscapes provides a framework for assessing the contribution of cold-water refuges to the success of migrating fishes, but any final determination will depend on analyzing fish survival and health for their entire migration, water temperature management goals and species recovery targets.

美国哥伦比亚河冷水保护区对成年奇努克鲑鱼和钢头鳟鱼生殖迁移走廊条件的贡献。
二恶英鱼类种群在洄游路线上面临多重挑战。这些挑战包括水质欠佳、采收以及纵向和横向连接障碍。影响洄游成功的因素之间的相互作用使评估改善河流洄游走廊沿岸洄游鱼类条件的管理选择具有挑战性。我们描述了一个空间显式模拟模型,该模型集成了秋洄游的奇努克鲑鱼(Oncorhynchus tshawytscha)和夏洄游的虹鳟(O. mykiss)在洄游过程中的复杂个体行为,响应了哥伦比亚河大范围内变化的栖息地条件,并将洄游走廊条件与鱼类状况结果联系起来。该模型是围绕一个机械行为决策树建立的,该决策树驱动鱼在模拟环境中的个体相互作用。通过模拟几种具有热避难所可用性的热景观,我们研究了冷水避难所的行为热调节如何影响洄游鱼类的条件。迁移走廊模拟模型的结果表明,冷水避难所可以缓解暴露在高水温下的压力,但对成年迁移的能源节约没有实质性的贡献。哥伦比亚河的模拟降温减少了对冷水避难所的依赖,迁徙的能量消耗也略有减少。这种模拟热景观的建模为评估冷水保护区对鱼类成功洄游的贡献提供了一个框架,但任何最终的决定都将取决于对鱼类整个洄游过程的生存和健康状况、水温管理目标和物种恢复目标的分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
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