Testing models of increasing complexity to develop ecosystem-informed fisheries advice

IF 5.6 1区 农林科学 Q1 FISHERIES Fish and Fisheries Pub Date : 2024-02-28 DOI:10.1111/faf.12820
Matthew D. Robertson, Noel G. Cadigan, Paul M. Regular, Mariano Koen-Alonso, Frédéric Cyr, Fan Zhang, Tyler D. Eddy
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Abstract

Despite continued calls for the application of ecosystem-based fisheries management, tactical fisheries management continues to be heavily reliant on single-species stock assessments. These stock assessments rarely quantitatively integrate the effects of ecosystem processes on fish stock productivity. This lack of integration is ultimately driven by the complexity of interactions between populations, ecosystems and fisheries, which produces uncertainty when defining which processes to include and how to include them. Models developed using a structured hypothesis testing framework would allow formalizing uncertainties while underscoring the importance of incorporating different population and ecosystem processes to explain non-stationary stock productivity. Here, we develop a conceptual framework for extending and comparing population dynamics models of increasing complexity. We illustrate the utility of the framework by investigating the population and ecosystem processes that most likely affected the differential recovery of two flatfish populations (American plaice and yellowtail flounder) on the Newfoundland Grand Banks over the past three decades. We found that yellowtail flounder population dynamics were primarily driven by recruitment variability, which was negatively affected by warmer climatological conditions, as indicated by an integrated regional climate index. Meanwhile, American plaice population dynamics were affected by a combination of temporal variability in recruitment and natural mortality, where natural mortality increased during colder than average conditions. By exploring hypotheses about the effects of population and ecosystem processes on population dynamics, this modelling framework will improve understanding about the drivers of shifts in population productivity while serving as a transparent and robust approach to support ecosystem-based fisheries management.

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测试复杂性不断增加的模型,以制定基于生态系统的渔业建议
尽管人们不断呼吁应用基于生态系统的渔业管理,但战术性渔业管理仍然严重依赖单一鱼种的鱼量评估。这些种群评估很少定量整合生态系统过程对鱼类种群生产力的影响。缺乏整合的最终原因是种群、生态系统和渔业之间相互作用的复杂性,这在确定包括哪些过程以及如何包括这些过程时产生了不确定性。利用结构化假设检验框架开发的模型将使不确定性正规化,同时强调纳入不同种群和生态系统过程对解释非稳态种群生产力的重要性。在此,我们建立了一个概念框架,用于扩展和比较日益复杂的种群动力学模型。我们通过研究最有可能影响纽芬兰大浅滩两个比目鱼种群(美洲鲽和黄尾比目鱼)在过去三十年中不同恢复的种群和生态系统过程,来说明该框架的实用性。我们发现,黄尾鲽的种群动态主要受招募变异的驱动,而招募变异受气候变暖的负面影响,如综合区域气候指数所示。与此同时,美洲鲽的种群动态则受到补充量的时间变化和自然死亡率的综合影响,其中自然死亡率在比平均温度更冷的条件下有所增加。通过探索种群和生态系统过程对种群动态影响的假设,该建模框架将加深对种群生产力变化驱动因素的理解,同时作为一种透明、稳健的方法,支持基于生态系统的渔业管理。
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来源期刊
Fish and Fisheries
Fish and Fisheries 农林科学-渔业
CiteScore
12.80
自引率
6.00%
发文量
83
期刊介绍: Fish and Fisheries adopts a broad, interdisciplinary approach to the subject of fish biology and fisheries. It draws contributions in the form of major synoptic papers and syntheses or meta-analyses that lay out new approaches, re-examine existing findings, methods or theory, and discuss papers and commentaries from diverse areas. Focal areas include fish palaeontology, molecular biology and ecology, genetics, biochemistry, physiology, ecology, behaviour, evolutionary studies, conservation, assessment, population dynamics, mathematical modelling, ecosystem analysis and the social, economic and policy aspects of fisheries where they are grounded in a scientific approach. A paper in Fish and Fisheries must draw upon all key elements of the existing literature on a topic, normally have a broad geographic and/or taxonomic scope, and provide general points which make it compelling to a wide range of readers whatever their geographical location. So, in short, we aim to publish articles that make syntheses of old or synoptic, long-term or spatially widespread data, introduce or consolidate fresh concepts or theory, or, in the Ghoti section, briefly justify preliminary, new synoptic ideas. Please note that authors of submissions not meeting this mandate will be directed to the appropriate primary literature.
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