The Paradox of Increasing Summertime Soil Moisture in the Continental USA

Key Takeaways:

• Contrary to climate model predictions of drier conditions, 57% of the continental USA shows increasing summertime soil moisture trends from 2011 to 2020.
• A new two-layer land surface model developed by Vargas, Trevino, and Huybers (2024) investigates these unexpected trends using observed data on precipitation, solar radiation, vapor pressure, and snowmelt.
• Internal precipitation variability is the primary driver of the observed soil moisture increase during this period.
• The effects of surface air warming and plant responses to higher CO2 levels are present but minor and somewhat offsetting on a decadal scale.
• Future soil moisture trends are expected to be governed by internal precipitation variability on a decadal scale, with long-term trends hinging on highly uncertain precipitation changes.

Addressing the Climate Model Conundrum

Climate models have long forecasted a decrease in summertime soil moisture across the continental United States due to anthropogenic climate change, a prediction aligned with various aridity indices. However, a decade of observations from ground probes and satellites tells a different story, with over half of the region experiencing a notable increase in soil moisture during the summer months of 2011 to 2020. This discrepancy between models and observations has prompted a deeper investigation into the underlying mechanisms.

A Novel Approach to Understanding Soil Moisture Trends

To shed light on this paradox, Vargas, Trevino, and Huybers (2024) developed an innovative two-layer land surface model designed to simulate surface temperature and USA soil moisture based on actual data on precipitation, solar radiation, vapor pressure, and snowmelt. This approach allows for a more nuanced understanding of the factors influencing soil moisture levels.

Key Drivers of Soil Moisture Variability

The comprehensive analysis revealed that internal precipitation variability plays the most significant role in the positive soil moisture trends observed over the past decade. While the warming of surface air and the physiological response of plants to elevated atmospheric CO2 levels also contribute to these trends, their impact is minor. It tends to balance out when viewed over shorter, decadal timescales.

Looking to the Future

The findings of Vargas, Trevino, and Huybers (2024) suggest that decadal trends in soil moisture will continue to be predominantly influenced by variations in precipitation. However, the long-term outlook for soil moisture levels remains uncertain and heavily dependent on future changes in precipitation patterns, which are currently difficult to predict accurately.

Implications for Climate Adaptation and Water Management

Understanding soil moisture dynamics is critical for agriculture, water resource management, and climate adaptation strategies. This study provides valuable insights into the complex interactions between climate variables and soil moisture, highlighting the need for flexible, informed approaches to managing water resources in the face of climate variability and change.

Read the rest here.