A family of process-based models to simulate landscape use by multiple taxa

IF 4 2区环境科学与生态学 Q1 ECOLOGY

Landscape Ecology Pub Date : 2024-05-02 DOI:10.1007/s10980-024-01866-4

Emma Gardner, Robert A. Robinson, Angela Julian, Katherine Boughey, Steve Langham, Jenny Tse-Leon, Sergei Petrovskii, David J. Baker, Chloe Bellamy, Andrew Buxton, Samantha Franks, Chris Monk, Nicola Morris, Kirsty J. Park, Silviu Petrovan, Katie Pitt, Rachel Taylor, Rebecca K. Turner, Steven J. R. Allain, Val Bradley, Richard K. Broughton, Mandy Cartwright, Kevin Clarke, Jon Cranfield, Elisa Fuentes-Montemayor, Robert Gandola, Tony Gent, Shelley A. Hinsley, Thomas Madsen, Chris Reading, John W. Redhead, Sonia Reveley, John Wilkinson, Carol Williams, Ian Woodward, John Baker, Philip Briggs, Sheila Dyason, Steve Langton, Ashlea Mawby, Richard F. Pywell, James M. Bullock

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引用次数: 0

Abstract

Context

Land-use change is a key driver of biodiversity loss. Models that accurately predict how biodiversity might be affected by land-use changes are urgently needed, to help avoid further negative impacts and inform landscape-scale restoration projects. To be effective, such models must balance model realism with computational tractability and must represent the different habitat and connectivity requirements of multiple species.

Objectives

We explored the extent to which process-based modelling might fulfil this role, examining feasibility for different taxa and potential for informing real-world decision-making.

Methods

We developed a family of process-based models (*4pop) that simulate landscape use by birds, bats, reptiles and amphibians, derived from the well-established poll4pop model (designed to simulate bee populations). Given landcover data, the models predict spatially-explicit relative abundance by simulating optimal home-range foraging, reproduction, dispersal of offspring and mortality. The models were co-developed by researchers, conservation NGOs and volunteer surveyors, parameterised using literature data and expert opinion, and validated against observational datasets collected across Great Britain.

Results

The models were able to simulate habitat specialists, generalists, and species requiring access to multiple habitats for different types of resources (e.g. breeding vs foraging). We identified model refinements required for some taxa and considerations for modelling further species/groups.

Conclusions

We suggest process-based models that integrate multiple forms of knowledge can assist biodiversity-inclusive decision-making by predicting habitat use throughout the year, expanding the range of species that can be modelled, and enabling decision-makers to better account for landscape context and habitat configuration effects on population persistence.

Abstract Image

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基于过程的模型系列，模拟多类群对景观的利用

背景土地使用变化是生物多样性丧失的主要驱动因素。目前迫切需要能准确预测生物多样性如何受到土地利用变化影响的模型，以帮助避免进一步的负面影响，并为景观尺度恢复项目提供信息。我们探索了基于过程的建模可在多大程度上发挥这一作用，研究了不同分类群的可行性以及为现实世界决策提供信息的潜力。方法我们开发了一系列基于过程的模型（*4pop），模拟鸟类、蝙蝠、爬行动物和两栖动物对景观的利用，这些模型源自成熟的 poll4pop 模型（用于模拟蜜蜂种群）。在有土地覆盖数据的情况下，这些模型通过模拟最佳家园范围的觅食、繁殖、后代扩散和死亡率，预测空间明确的相对丰度。这些模型由研究人员、非政府保护组织和志愿调查人员共同开发，利用文献数据和专家意见设定参数，并根据在大不列颠收集的观测数据集进行验证。我们确定了一些类群需要对模型进行的改进，以及对更多物种/类群建模时需要考虑的因素。结论我们认为，基于过程的模型整合了多种形式的知识，可以通过预测全年的栖息地利用情况、扩大可建模物种的范围，以及使决策者能够更好地考虑景观环境和栖息地配置对种群持续性的影响，来协助生物多样性包容性决策。

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来源期刊

Landscape Ecology 环境科学-地球科学综合

CiteScore

8.30

自引率

7.70%

发文量

164

审稿时长

8-16 weeks

期刊介绍： Landscape Ecology is the flagship journal of a well-established and rapidly developing interdisciplinary science that focuses explicitly on the ecological understanding of spatial heterogeneity. Landscape Ecology draws together expertise from both biophysical and socioeconomic sciences to explore basic and applied research questions concerning the ecology, conservation, management, design/planning, and sustainability of landscapes as coupled human-environment systems. Landscape ecology studies are characterized by spatially explicit methods in which spatial attributes and arrangements of landscape elements are directly analyzed and related to ecological processes.