Drought as an emergent driver of ecological transformation in the twenty-first century

Wynne E. Moss; Shelley D. Crausbay; Imtiaz Rangwala; Jay W. Wason; Clay Trauernicht; Camille S. Stevens-Rumann; Anna Sala; Caitlin M. Rottler; Gregory T. Pederson; Brian W. Miller; Dawn R. Magness; Jeremy S. Littell; Lee E. Frelich; Abby G. Frazier; Kimberley T. Davis; Jonathan D. Coop; Jennifer M. Cartwright; Robert K. Booth

doi:10.1093/biosci/biae050

Drought as an emergent driver of ecological transformation in the twenty-first century

Wynne E. Moss
, Shelley D. Crausbay
, Imtiaz Rangwala
, Jay W. Wason
, Clay Trauernicht
, Camille S. Stevens-Rumann
, Anna Sala
, Caitlin M. Rottler
, Gregory T. Pederson
, Brian W. Miller
, Dawn R. Magness
, Jeremy S. Littell
, Lee E. Frelich
, Abby G. Frazier
, Kimberley T. Davis
, Jonathan D. Coop
, Jennifer M. Cartwright
, Robert K. Booth

Division of Biological and Biomedical Sciences

United States Geological Survey
United States Department of Agriculture
University of Colorado Boulder
University of Maine
University of Hawai'i at Mānoa
Colorado State University
University of Oklahoma
U.S. Department of the Interior
University of Minnesota Twin Cities
Clark University
University of Montana
Western Colorado University
Lehigh University

Research output: Contribution to journal › Article

43 Scopus citations

Abstract

Under climate change, ecosystems are experiencing novel drought regimes, often in combination with stressors that reduce resilience and amplify drought's impacts. Consequently, drought appears increasingly likely to push systems beyond important physiological and ecological thresholds, resulting in substantial changes in ecosystem characteristics persisting long after drought ends (i.e., ecological transformation). In the present article, we clarify how drought can lead to transformation across a wide variety of ecosystems including forests, woodlands, and grasslands. Specifically, we describe how climate change alters drought regimes and how this translates to impacts on plant population growth, either directly or through drought's interactions with factors such as land management, biotic interactions, and other disturbances. We emphasize how interactions among mechanisms can inhibit postdrought recovery and can shift trajectories toward alternate states. Providing a holistic picture of how drought initiates long-term change supports the development of risk assessments, predictive models, and management strategies, enhancing preparedness for a complex and growing challenge.

Original language	English
Pages (from-to)	524-538
Number of pages	15
Journal	BioScience
Volume	74
Issue number	8
DOIs	https://doi.org/10.1093/biosci/biae050
State	Published - Jul 10 2024

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action
SDG 15 Life on Land

Keywords

climate change
disturbance
drought
ecological transformation
vegetation shift

Access to Document

10.1093/biosci/biae050

Cite this

Moss, W. E., Crausbay, S. D., Rangwala, I., Wason, J. W., Trauernicht, C., Stevens-Rumann, C. S., Sala, A., Rottler, C. M., Pederson, G. T., Miller, B. W., Magness, D. R., Littell, J. S., Frelich, L. E., Frazier, A. G., Davis, K. T., Coop, J. D., Cartwright, J. M., & Booth, R. K. (2024). Drought as an emergent driver of ecological transformation in the twenty-first century. BioScience, 74(8), 524-538. https://doi.org/10.1093/biosci/biae050

@article{48b8678a902a40ca8f429151bbfed508,

title = "Drought as an emergent driver of ecological transformation in the twenty-first century",

abstract = "Under climate change, ecosystems are experiencing novel drought regimes, often in combination with stressors that reduce resilience and amplify drought's impacts. Consequently, drought appears increasingly likely to push systems beyond important physiological and ecological thresholds, resulting in substantial changes in ecosystem characteristics persisting long after drought ends (i.e., ecological transformation). In the present article, we clarify how drought can lead to transformation across a wide variety of ecosystems including forests, woodlands, and grasslands. Specifically, we describe how climate change alters drought regimes and how this translates to impacts on plant population growth, either directly or through drought's interactions with factors such as land management, biotic interactions, and other disturbances. We emphasize how interactions among mechanisms can inhibit postdrought recovery and can shift trajectories toward alternate states. Providing a holistic picture of how drought initiates long-term change supports the development of risk assessments, predictive models, and management strategies, enhancing preparedness for a complex and growing challenge.",

keywords = "climate change, disturbance, drought, ecological transformation, vegetation shift",

author = "Moss, \{Wynne E.\} and Crausbay, \{Shelley D.\} and Imtiaz Rangwala and Wason, \{Jay W.\} and Clay Trauernicht and Stevens-Rumann, \{Camille S.\} and Anna Sala and Rottler, \{Caitlin M.\} and Pederson, \{Gregory T.\} and Miller, \{Brian W.\} and Magness, \{Dawn R.\} and Littell, \{Jeremy S.\} and Frelich, \{Lee E.\} and Frazier, \{Abby G.\} and Davis, \{Kimberley T.\} and Coop, \{Jonathan D.\} and Cartwright, \{Jennifer M.\} and Booth, \{Robert K.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = jul,

day = "10",

doi = "10.1093/biosci/biae050",

language = "English",

volume = "74",

pages = "524--538",

journal = "BioScience",

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Moss, WE, Crausbay, SD, Rangwala, I, Wason, JW, Trauernicht, C, Stevens-Rumann, CS, Sala, A, Rottler, CM, Pederson, GT, Miller, BW, Magness, DR, Littell, JS, Frelich, LE, Frazier, AG, Davis, KT, Coop, JD, Cartwright, JM & Booth, RK 2024, 'Drought as an emergent driver of ecological transformation in the twenty-first century', BioScience, vol. 74, no. 8, pp. 524-538. https://doi.org/10.1093/biosci/biae050

TY - JOUR

T1 - Drought as an emergent driver of ecological transformation in the twenty-first century

AU - Moss, Wynne E.

AU - Crausbay, Shelley D.

AU - Rangwala, Imtiaz

AU - Wason, Jay W.

AU - Trauernicht, Clay

AU - Stevens-Rumann, Camille S.

AU - Sala, Anna

AU - Rottler, Caitlin M.

AU - Pederson, Gregory T.

AU - Miller, Brian W.

AU - Magness, Dawn R.

AU - Littell, Jeremy S.

AU - Frelich, Lee E.

AU - Frazier, Abby G.

AU - Davis, Kimberley T.

AU - Coop, Jonathan D.

AU - Cartwright, Jennifer M.

AU - Booth, Robert K.

PY - 2024/7/10

Y1 - 2024/7/10

N2 - Under climate change, ecosystems are experiencing novel drought regimes, often in combination with stressors that reduce resilience and amplify drought's impacts. Consequently, drought appears increasingly likely to push systems beyond important physiological and ecological thresholds, resulting in substantial changes in ecosystem characteristics persisting long after drought ends (i.e., ecological transformation). In the present article, we clarify how drought can lead to transformation across a wide variety of ecosystems including forests, woodlands, and grasslands. Specifically, we describe how climate change alters drought regimes and how this translates to impacts on plant population growth, either directly or through drought's interactions with factors such as land management, biotic interactions, and other disturbances. We emphasize how interactions among mechanisms can inhibit postdrought recovery and can shift trajectories toward alternate states. Providing a holistic picture of how drought initiates long-term change supports the development of risk assessments, predictive models, and management strategies, enhancing preparedness for a complex and growing challenge.

AB - Under climate change, ecosystems are experiencing novel drought regimes, often in combination with stressors that reduce resilience and amplify drought's impacts. Consequently, drought appears increasingly likely to push systems beyond important physiological and ecological thresholds, resulting in substantial changes in ecosystem characteristics persisting long after drought ends (i.e., ecological transformation). In the present article, we clarify how drought can lead to transformation across a wide variety of ecosystems including forests, woodlands, and grasslands. Specifically, we describe how climate change alters drought regimes and how this translates to impacts on plant population growth, either directly or through drought's interactions with factors such as land management, biotic interactions, and other disturbances. We emphasize how interactions among mechanisms can inhibit postdrought recovery and can shift trajectories toward alternate states. Providing a holistic picture of how drought initiates long-term change supports the development of risk assessments, predictive models, and management strategies, enhancing preparedness for a complex and growing challenge.

KW - climate change

KW - disturbance

KW - drought

KW - ecological transformation

KW - vegetation shift

UR - https://www.scopus.com/pages/publications/85204156910

U2 - 10.1093/biosci/biae050

DO - 10.1093/biosci/biae050

M3 - Article

AN - SCOPUS:85204156910

SN - 0006-3568

VL - 74

SP - 524

EP - 538

JO - BioScience

JF - BioScience

IS - 8

ER -

Drought as an emergent driver of ecological transformation in the twenty-first century

Abstract

UN SDGs

Keywords

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