Disentangling Ecosystem Necromass Dynamics for Biodiversity Conservation

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-04-30 DOI:10.1007/s10021-024-00907-y
Philip S. Barton, Nick Schultz, Nathan J. Butterworth, Michael D. Ulyshen, Patricia Mateo-Tomás, Thomas M. Newsome
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Abstract

Global environmental change has redistributed earth’s biomass and the inputs and dynamics of basal detrital resources in ecosystems, contributing to the decline of biodiversity. Yet efforts to manage detrital necromass for biodiversity conservation are often overlooked or consider only singular resource types for focal species groups. We argue there is a significant opportunity to broaden our perspective of the spatiotemporal complexity among multiple necromass types for innovative biodiversity conservation. Here, we introduce an ecosystem-scale perspective to disentangling the spatial and temporal characteristics of multiple and distinct forms of necromass and their associated biota. We show that terrestrial and aquatic ecosystems contain a diversity of necromass types, each with contrasting temporal frequencies and magnitudes, and spatial density and configurations. By conceptualising an ecosystem in this way, we demonstrate that specific necromass dynamics can be identified and targeted for management that benefits the unique spatiotemporal requirements of dependent decomposer organisms and their critical role in ecosystem biomass conversion and nutrient recycling. We encourage conservation practitioners to think about necromass quantity, timing of inputs, spatial dynamics, and to engage with researchers to deepen our knowledge of how necromass might be manipulated to exploit the distinct attributes of different necromass types to help meet biodiversity conservation goals.

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为保护生物多样性而厘清生态系统死亡动态
全球环境变化重新分配了地球的生物量以及生态系统中基底碎屑资源的输入和动态,导致生物多样性减少。然而,为保护生物多样性而管理碎屑资源的工作往往被忽视,或者只考虑重点物种群的单一资源类型。我们认为,为创新性地保护生物多样性,我们有很大的机会扩大我们对多种碎屑资源类型的时空复杂性的认识。在这里,我们引入了生态系统尺度的视角来分解多种不同形式的尸块及其相关生物群的时空特征。我们的研究表明,陆地和水生生态系统包含多种类型的尸块,每种尸块的时间频率和规模、空间密度和结构都截然不同。通过以这种方式对生态系统进行概念化,我们证明了可以识别特定的腐肉动态,并有针对性地进行管理,以满足依赖性分解生物独特的时空要求,以及它们在生态系统生物量转换和养分循环中的关键作用。我们鼓励保护工作者思考坏死物质的数量、输入时间、空间动态,并与研究人员合作,加深我们对如何操纵坏死物质的认识,利用不同坏死物质类型的独特属性,帮助实现生物多样性保护目标。
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CiteScore
7.20
自引率
4.30%
发文量
567
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