Distinguishing Short‐Term Versus Long‐Term Responses in Cover‐Class Structured Community Dynamics: A Test With Grassland Drought Response

ABSTRACT Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long‐term (asymptotic) behaviour, potentially neglecting short‐term (transient) beh...

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Published inEcology letters Vol. 28; no. 8; pp. e70182 - n/a
Main Authors Gupta, Aryaman, Gascoigne, Samuel J. L., Barabás, György, Blonder, Benjamin Wong, Qi, Man, Fenollosa, Erola, Thornley, Rachael, Hernandez, Christina, Hector, Andy, Salguero‐Gómez, Roberto
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.08.2025
John Wiley and Sons Inc
Subjects
Climate Change
disturbance
Disturbances
Drought
Droughts
Dynamics
extreme precipitation
Fabaceae - physiology
Forbs
functional group
Functional groups
Grasses
Grassland
Grasslands
integral projection model (IPM)
interspecific interactions
Legumes
Letter
Models, Biological
Poaceae - physiology
Population Dynamics
Precipitation
Projection model
pseudospectra
stress gradient hypothesis
transient instability
disturbance
extreme precipitation
grasslands
pseudospectra
stress gradient hypothesis
transient instability
functional group
integral projection model (IPM)
interspecific interactions
Online AccessGet full text
ISSN1461-023X
1461-0248
1461-0248
DOI10.1111/ele.70182

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Abstract ABSTRACT Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long‐term (asymptotic) behaviour, potentially neglecting short‐term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short‐ and long‐term responses of three functional groups (grasses, legumes, and non‐leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover‐class structure and inter‐cover‐class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data‐wise inexpensive assessment of whether transient dynamics drive community responses to disturbances. We use Integral Projection Models (IPMs) and pseudospectral theory to track short‐term (transient) dynamics of a grassland subject to experimental precipitation shifts. We show that the cover‐class structure of functional groups makes them transiently unstable but asymptotically stable, that is, disturbances initially amplify before dissipating. The pseudospectra of community matrices from those IPMs enable computationally and data‐light assessment of transient community responses to disturbances.
AbstractList Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long-term (asymptotic) behaviour, potentially neglecting short-term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short- and long-term responses of three functional groups (grasses, legumes, and non-leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover-class structure and inter-cover-class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data-wise inexpensive assessment of whether transient dynamics drive community responses to disturbances.
Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long‐term (asymptotic) behaviour, potentially neglecting short‐term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short‐ and long‐term responses of three functional groups (grasses, legumes, and non‐leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover‐class structure and inter‐cover‐class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data‐wise inexpensive assessment of whether transient dynamics drive community responses to disturbances. We use Integral Projection Models (IPMs) and pseudospectral theory to track short‐term (transient) dynamics of a grassland subject to experimental precipitation shifts. We show that the cover‐class structure of functional groups makes them transiently unstable but asymptotically stable, that is, disturbances initially amplify before dissipating. The pseudospectra of community matrices from those IPMs enable computationally and data‐light assessment of transient community responses to disturbances.
Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long-term (asymptotic) behaviour, potentially neglecting short-term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short- and long-term responses of three functional groups (grasses, legumes, and non-leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover-class structure and inter-cover-class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data-wise inexpensive assessment of whether transient dynamics drive community responses to disturbances.Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long-term (asymptotic) behaviour, potentially neglecting short-term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short- and long-term responses of three functional groups (grasses, legumes, and non-leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover-class structure and inter-cover-class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data-wise inexpensive assessment of whether transient dynamics drive community responses to disturbances.
ABSTRACT Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming harder to predict since models typically simulate long‐term (asymptotic) behaviour, potentially neglecting short‐term (transient) behaviour. Here, we use cover data from an experiment performed over 8 years to model short‐ and long‐term responses of three functional groups (grasses, legumes, and non‐leguminous forbs) to precipitation extremes. We use Integral Projection Models (IPMs) and pseudospectral theory to track transient grassland community dynamics driven by response lags and interannual shifts. We show that the cover‐class structure and inter‐cover‐class interactions of functional groups make them transiently unstable but asymptotically stable, that is, disturbances are initially amplified before eventually dissipating. We also show that grasses dominate under irrigation, while legumes and forbs dominate under drought. We demonstrate that the pseudospectra of IPMs enable computationally and data‐wise inexpensive assessment of whether transient dynamics drive community responses to disturbances. We use Integral Projection Models (IPMs) and pseudospectral theory to track short‐term (transient) dynamics of a grassland subject to experimental precipitation shifts. We show that the cover‐class structure of functional groups makes them transiently unstable but asymptotically stable, that is, disturbances initially amplify before dissipating. The pseudospectra of community matrices from those IPMs enable computationally and data‐light assessment of transient community responses to disturbances.
Author Gupta, Aryaman
Thornley, Rachael
Hernandez, Christina
Fenollosa, Erola
Gascoigne, Samuel J. L.
Salguero‐Gómez, Roberto
Blonder, Benjamin Wong
Barabás, György
Hector, Andy
Qi, Man
AuthorAffiliation 3 School of Biological Sciences University of Aberdeen, Zoology Building Aberdeen UK
5 Institute of Evolution, Centre for Ecological Research Budapest Hungary
4 Division of Biology, Department of Physics, Chemistry and Biology (IFM) Linköping University Linköping Sweden
2 Mathematical Institute University of Oxford Oxford UK
1 Department of Biology University of Oxford Oxford UK
6 Department of Environmental Science, Policy, and Management University of California Berkeley California USA
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– name: 4 Division of Biology, Department of Physics, Chemistry and Biology (IFM) Linköping University Linköping Sweden
– name: 5 Institute of Evolution, Centre for Ecological Research Budapest Hungary
– name: 6 Department of Environmental Science, Policy, and Management University of California Berkeley California USA
– name: 1 Department of Biology University of Oxford Oxford UK
– name: 3 School of Biological Sciences University of Aberdeen, Zoology Building Aberdeen UK
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  surname: Qi
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  organization: University of Oxford
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  surname: Hernandez
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  surname: Hector
  fullname: Hector, Andy
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– sequence: 10
  givenname: Roberto
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  surname: Salguero‐Gómez
  fullname: Salguero‐Gómez, Roberto
  email: rob.salguero@biology.ox.ac.uk
  organization: University of Oxford
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Issue 8
Keywords disturbance
extreme precipitation
grasslands
pseudospectra
stress gradient hypothesis
transient instability
functional group
integral projection model (IPM)
interspecific interactions
Language English
License Attribution
2025 The Author(s). Ecology Letters published by John Wiley & Sons Ltd.
This is an open access article under the terms of the http://creativecommons.org/licenses/by/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
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This work was supported by Natural Environment Research Council, NE/X013766/1.
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Funding: This work was supported by Natural Environment Research Council, NE/X013766/1.
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Snippet ABSTRACT Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and...
Climate change is increasing the magnitude and frequency of precipitation extremes. Consequently, grassland community dynamics are destabilising and becoming...
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SourceType Open Access Repository
Aggregation Database
Index Database
Publisher
StartPage e70182
SubjectTerms Climate Change
disturbance
Disturbances
Drought
Droughts
Dynamics
extreme precipitation
Fabaceae - physiology
Forbs
functional group
Functional groups
Grasses
Grassland
Grasslands
integral projection model (IPM)
interspecific interactions
Legumes
Letter
Models, Biological
Poaceae - physiology
Population Dynamics
Precipitation
Projection model
pseudospectra
stress gradient hypothesis
transient instability
Title Distinguishing Short‐Term Versus Long‐Term Responses in Cover‐Class Structured Community Dynamics: A Test With Grassland Drought Response
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fele.70182
https://www.ncbi.nlm.nih.gov/pubmed/40801190
https://www.proquest.com/docview/3244167889
https://www.proquest.com/docview/3239118385
https://pubmed.ncbi.nlm.nih.gov/PMC12344748
https://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-217218
Volume 28
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