Multi-scale environmental factors explain fish losses and refuge quality in drying waterholes of Cooper Creek, an Australian arid-zone river

IF 1.5 4区环境科学与生态学 Q2 FISHERIES

Marine and Freshwater Research Pub Date : 2010-09-03 DOI:10.1071/MF09096

A. Arthington, J. Olden, S. Balcombe, M. Thoms

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引用次数: 49

Abstract

Many rivers experience intermittent flows naturally or as a consequence of water abstraction. Climate change is likely to exacerbate flow variability such that dry spells may become more common. It is important to understand the ecological consequences of flow intermittency and habitat fragmentation in rivers, and to identify and protect habitat patches that provide refugia for aquatic biota. This paper explores environmental factors influencing dry season fish losses from isolated waterbodies in Cooper Creek, an unregulated arid-zone river in the Lake Eyre Basin, Australia. Multivariate ordination techniques and classification and regression trees (CART) were used to decompose species-environment relationships into a hierarchically structured data set, and to determine factors explaining changes in fish assemblage structure and species losses over a single dry season. Canonical correspondence analysis (CCA) explained 74% of fish assemblage change in terms of waterhole morphology (wetted perimeter, depth), habitat structure (bench development, off-take channels), waterhole quality (eroded banks, gross primary production), the size of surrounding floodplains and the relative isolation of waterholes. Classification trees for endemic and restricted species reaffirmed the importance of these waterhole and floodplain variables as drivers of fish losses. The CCA and CART models offer valuable tools for identification of refugia in Cooper Creek and, possibly, other dryland rivers.

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多尺度的环境因素解释了澳大利亚干旱地区河流库柏溪干涸水坑的鱼类损失和避难所质量

许多河流经历了自然的间歇流动或作为抽水的结果。气候变化可能会加剧水流的可变性，因此干旱期可能会变得更加普遍。了解河流水流间断性和生境破碎化的生态后果，识别和保护为水生生物提供避难所的生境斑块具有重要意义。本文探讨了影响澳大利亚艾尔湖流域一条不受管制的干旱区河流库柏溪(Cooper Creek)孤立水体旱季鱼类损失的环境因素。利用多元排序技术和分类回归树(CART)将物种-环境关系分解为层次结构数据集，并确定单个旱季鱼类组合结构变化和物种损失的因素。典型对应分析(CCA)解释了74%的鱼类组合变化，包括水孔形态(湿润周长、深度)、栖息地结构(滩发育、取水通道)、水孔质量(侵蚀堤岸、总初级产量)、周围洪泛平原的大小和水孔的相对隔离。地方性和限制性物种的分类树再次确认了这些水坑和洪泛区变量作为鱼类损失驱动因素的重要性。CCA和CART模型为识别库柏溪(Cooper Creek)以及可能的其他旱地河流中的难民提供了宝贵的工具。

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来源期刊

Marine and Freshwater Research 环境科学-海洋学

CiteScore

4.60

自引率

5.60%

发文量

审稿时长

3.8 months

期刊介绍： Marine and Freshwater Research is an international and interdisciplinary journal publishing contributions on all aquatic environments. The journal’s content addresses broad conceptual questions and investigations about the ecology and management of aquatic environments. Environments range from groundwaters, wetlands and streams to estuaries, rocky shores, reefs and the open ocean. Subject areas include, but are not limited to: aquatic ecosystem processes, such as nutrient cycling; biology; ecology; biogeochemistry; biogeography and phylogeography; hydrology; limnology; oceanography; toxicology; conservation and management; and ecosystem services. Contributions that are interdisciplinary and of wide interest and consider the social-ecological and institutional issues associated with managing marine and freshwater ecosystems are welcomed. Marine and Freshwater Research is a valuable resource for researchers in industry and academia, resource managers, environmental consultants, students and amateurs who are interested in any aspect of the aquatic sciences. Marine and Freshwater Research is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science.