TY - JOUR
T1 - Local moisture recycling across the globe
AU - Theeuwen, Jolanda
AU - Staal, Arie
AU - Tuinenburg, Obbe
AU - Hamelers, Bert
AU - Dekker, Stefan
N1 - Funding Information:
The authors wish to thank Patrick Keys, Ruud van der Ent, and the anonymous reviewer for commenting on earlier versions of this paper. This work was performed in the cooperation framework of Wetsus, European Centre of Excellence for Sustainable Water Technology ( https://www.wetsus.nl/ , last access: 7 July 2022). Wetsus is co-funded by the Dutch Ministry of Economic Affairs and Climate Policy, the Northern Netherlands Provinces, and the Province of Fryslân. The authors would like to thank the participants of the Wetsus natural water production theme for fruitful discussions and financial support. Arie Staal acknowledges support from the Dutch Research Council (NWO) Talent Programme (grant no. VI.Veni.202.170). Obbe A. Tuinenburg acknowledges support from the NWO Innovational Research Incentives Scheme Veni research programme (grant no. 016.veni.171.019).
Funding Information:
This research has been supported by the Aard- en Levenswetenschappen, Nederlandse Organisatie voor Wetenschappelijk Onderzoek (grant nos. VI.Veni.202.170 and 016.veni.171.019).
Publisher Copyright:
© 2023 Jolanda J. E. Theeuwen et al.
PY - 2023/4/4
Y1 - 2023/4/4
N2 - Changes in evaporation over land affect terrestrial precipitation via atmospheric moisture recycling and, consequently, freshwater availability. Although global moisture recycling at regional and continental scales is relatively well understood, the patterns of local moisture recycling and the main variables that impact it remain unknown. We calculate the local moisture recycling ratio (LMR) as the fraction of evaporated moisture that precipitates within a distance of 0.5° (typically 50 km) of its source, identify variables that correlate with it over land globally, and study its model dependency. We derive the seasonal and annual LMR using a 10-year climatology (2008-2017) of monthly averaged atmospheric moisture connections at a scale of 0.5° obtained from a Lagrangian atmospheric moisture tracking model. We find that, annually, an average of 1.7% (SD of 1.1%) of evaporated moisture returns as precipitation locally, although with large temporal and spatial variability, and the LMR peaks in summer and over wet and mountainous regions. Our results show that wetness, orography, latitude, convective available potential energy, wind speed, and total cloud cover correlate clearly with the LMR, indicating that wet regions with little wind and strong ascending air are particularly favourable for a high LMR. Finally, we find that spatial patterns of local recycling are consistent between different models, yet the magnitude of recycling varies. Our results can be used to study the impacts of evaporation changes on local precipitation, with implications for, for example, regreening and water management.
AB - Changes in evaporation over land affect terrestrial precipitation via atmospheric moisture recycling and, consequently, freshwater availability. Although global moisture recycling at regional and continental scales is relatively well understood, the patterns of local moisture recycling and the main variables that impact it remain unknown. We calculate the local moisture recycling ratio (LMR) as the fraction of evaporated moisture that precipitates within a distance of 0.5° (typically 50 km) of its source, identify variables that correlate with it over land globally, and study its model dependency. We derive the seasonal and annual LMR using a 10-year climatology (2008-2017) of monthly averaged atmospheric moisture connections at a scale of 0.5° obtained from a Lagrangian atmospheric moisture tracking model. We find that, annually, an average of 1.7% (SD of 1.1%) of evaporated moisture returns as precipitation locally, although with large temporal and spatial variability, and the LMR peaks in summer and over wet and mountainous regions. Our results show that wetness, orography, latitude, convective available potential energy, wind speed, and total cloud cover correlate clearly with the LMR, indicating that wet regions with little wind and strong ascending air are particularly favourable for a high LMR. Finally, we find that spatial patterns of local recycling are consistent between different models, yet the magnitude of recycling varies. Our results can be used to study the impacts of evaporation changes on local precipitation, with implications for, for example, regreening and water management.
UR - http://www.scopus.com/inward/record.url?scp=85152769424&partnerID=8YFLogxK
U2 - 10.5194/hess-27-1457-2023
DO - 10.5194/hess-27-1457-2023
M3 - Article
SN - 1027-5606
VL - 27
SP - 1457
EP - 1476
JO - Hydrology and Earth System Sciences
JF - Hydrology and Earth System Sciences
IS - 7
ER -