Rising temperature drives tipping points in mutualistic networks

Rising temperature drives tipping points in mutualistic networks

The effect of climate warming on species' physiological parameters, including growth rate, mortality rate and handling time, is well established from empirical data. However, with an alarming rise in global temperature more than ever, predicting the interactive influence of these changes on mut...

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Bibliographic Details
Published in:Royal Society open science Vol. 10; no. 2; p. 221363
Main Authors: Bhandary, Subhendu, Deb, Smita, Sharathi Dutta, Partha
Format: Journal Article
Language:English
Published: England The Royal Society 01-02-2023
Subjects:
climate warming
community collapse
ecological networks
Mathematics
mutualistic communities
tipping points
tipping points
ecological networks
mutualistic communities
community collapse
climate warming
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Summary:The effect of climate warming on species' physiological parameters, including growth rate, mortality rate and handling time, is well established from empirical data. However, with an alarming rise in global temperature more than ever, predicting the interactive influence of these changes on mutualistic communities remains uncertain. Using 139 real plant-pollinator networks sampled across the globe and a modelling approach, we study the impact of species' individual thermal responses on mutualistic communities. We show that at low mutualistic strength plant-pollinator networks are at potential risk of rapid transitions at higher temperatures. Evidently, generalist species play a critical role in guiding tipping points in mutualistic networks. Further, we derive stability criteria for the networks in a range of temperatures using a two-dimensional reduced model. We identify network structures that can ascertain the delay of a community collapse. Until the end of this century, on account of increasing climate warming many real mutualistic networks are likely to be under the threat of sudden collapse, and we frame strategies to mitigate this. Together, our results indicate that knowing individual species' thermal responses and network structure can improve predictions for communities facing rapid transitions.
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Electronic supplementary material is available online at https://doi.org/10.6084/m9.figshare.c.6387947.
ISSN:2054-5703
2054-5703
DOI:10.1098/rsos.221363