TY - JOUR
T1 - Ecohydrological decoupling under changing disturbances and climate
AU - McDowell, Nate G.
AU - Anderson-Teixeira, Kristina
AU - Biederman, Joel A.
AU - Breshears, David D.
AU - Fang, Yilin
AU - Fernández-de-Uña, Laura
AU - Graham, Emily B.
AU - Mackay, D. Scott
AU - McDonnell, Jeffrey J.
AU - Moore, Georgianne W.
AU - Nehemy, Magali F.
AU - Stevens Rumann, Camille S.
AU - Stegen, James
AU - Tague, Naomi
AU - Turner, Monica G.
AU - Chen, Xingyuan
N1 - Publisher Copyright:
© 2023 Battelle Memorial Institute, The Author(s)
PY - 2023/3/17
Y1 - 2023/3/17
N2 - Terrestrial disturbances are increasing in frequency and severity, perturbing the hydrologic cycle by altering vegetation-mediated water use and microclimate. Here, we synthesize the literature on post-disturbance ecohydrological coupling, including the mechanistic relationship between vegetation and streamflow, under changing disturbance regimes, atmospheric CO2, and climate. Disturbance can cause decoupling between transpiration and streamflow by altering the connectivity, size, availability, and spatial distribution of their source pools. Successional trajectories influence the dynamics of source water partitioning. Changing climate and disturbance regimes can alter succession and prolong decoupling. Increasing rates, severity, and spread of disturbances along with warming could promote greater decoupling globally. From this review emerges a framework of testable hypotheses that identify the critical processes regulating ecohydrological coupling and provide a roadmap for future research. Accurate prediction of post-disturbance coupling requires understanding the degree of hydraulic connectivity between source water pools and their response to succession under changing disturbance and climate regimes.
AB - Terrestrial disturbances are increasing in frequency and severity, perturbing the hydrologic cycle by altering vegetation-mediated water use and microclimate. Here, we synthesize the literature on post-disturbance ecohydrological coupling, including the mechanistic relationship between vegetation and streamflow, under changing disturbance regimes, atmospheric CO2, and climate. Disturbance can cause decoupling between transpiration and streamflow by altering the connectivity, size, availability, and spatial distribution of their source pools. Successional trajectories influence the dynamics of source water partitioning. Changing climate and disturbance regimes can alter succession and prolong decoupling. Increasing rates, severity, and spread of disturbances along with warming could promote greater decoupling globally. From this review emerges a framework of testable hypotheses that identify the critical processes regulating ecohydrological coupling and provide a roadmap for future research. Accurate prediction of post-disturbance coupling requires understanding the degree of hydraulic connectivity between source water pools and their response to succession under changing disturbance and climate regimes.
UR - http://www.scopus.com/inward/record.url?scp=85163661558&partnerID=8YFLogxK
U2 - 10.1016/j.oneear.2023.02.007
DO - 10.1016/j.oneear.2023.02.007
M3 - Systematic review
AN - SCOPUS:85163661558
SN - 2590-3330
VL - 6
SP - 251
EP - 266
JO - One Earth
JF - One Earth
IS - 3
ER -