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.
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024/8/1
Y1 - 2024/8/1
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 - http://www.scopus.com/inward/record.url?scp=85204156910&partnerID=8YFLogxK
U2 - 10.1093/biosci/biae050
DO - 10.1093/biosci/biae050
M3 - Review article
AN - SCOPUS:85204156910
SN - 0006-3568
VL - 74
SP - 524
EP - 538
JO - BioScience
JF - BioScience
IS - 8
ER -