Abstract
Soil moisture-precipitation (SM-P) feedback significantly influences the terrestrial water and energy cycles. However, the sign of the feedback and the associated physical mechanism have been debated, leaving a research gap regarding global water and climate changes. Based on Koster’s framework, we estimate SM-P feedback using satellite remote sensing and ground observation data sets. Methodologically, the sign of the feedback is identified by the correlation between monthly soil moisture and next-month precipitation. The physical mechanism is investigated through coupling precipitation and soil moisture (P-SM), soil moisture ad evapotranspiration (SM-E) and evapotranspiration and precipitation (E-P) correlations. Our results demonstrate that although positive SM-P feedback is predominant over land, non-negligible negative feedback occurs in dry and wet regions. Specifically, 43.75% and 40.16% of the negative feedback occurs in the arid and humid climate zones. Physically, negative SM-P feedback depends on the SM-E correlation. In dry regions, evapotranspiration change is soil moisture limited. In wet regions, evapotranspiration change is energy limited. We conclude that the complex SM-E correlation results in negative SM-P feedback in dry and wet regions, and the cause varies based on the environmental and climatic conditions.
Highlights
Soil moisture-precipitation (SM-P) feedback significantly influences the terrestrial water and energy cycles
The global soil moisture increased slightly based on the relationship y = 0.0006x +0.2174 (R2 = 0.21, p < 0.001; where y and x represent the soil moisture and calendar year)
Positive feedback has been widely noted in previous studies, while negative feedback has been given less attention
Summary
Soil moisture-precipitation (SM-P) feedback significantly influences the terrestrial water and energy cycles. We conclude that the complex SM-E correlation results in negative SM-P feedback in dry and wet regions, and the cause varies based on the environmental and climatic conditions. The interactions between soil moisture and the hydrological variables are essential for understanding the physical mechanisms of global water and climate change. Most previous studies found positive correlations between soil moisture and precipitation[14,15,16] This process can be interpreted by the water and energy cycles. The opposite phenomenon has been observed in recent studies, which observed that more precipitation fell over dry soil due to the enhanced convective system[17,18] This phenomenon was further confirmed by studies of global water change, which revealed an overestimation trend based on the paradigm of “dry gets drier, wet gets wetter”[19,20]. The physical mechanism remains unclear and requires further investigation
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