We’ve spent decades talking about carbon — how much we emit, how much we need to cut. That conversation matters, but it is not the whole story. For over four billion years, water has been running Earth’s climate system, cycling through evaporation, transpiration and condensation, cooling the air and regulating temperature with extraordinary precision. That system depended on living soil: porous, rich with organic matter, built to hold water and release it slowly. It is now badly damaged — and restoring it is not a secondary climate strategy. It is an essential one.

This report was led by Rico Rau and Lu Yu from the Conscious Planet Save Soil initiative, who set out to make the science of the soil carbon sponge accessible to a global media audience without compromising its rigour. Rico coordinates youth engagement across major UN platforms and leads media outreach across Europe; Lu drives cross-country policy advocacy and international partnerships in support of soil health and agroecology. The collaboration was brought together by Cindy Eiritz, whose connections across the regenerative soil community made this project possible. Ben Fox, ecosystems engineer at Regenerate Earth, contributed scientific review on behalf of Walter Jehne — lending additional grounding in biohydrological function and the practical science of soil restoration.

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Executive Summary 

While contemporary climate mitigation discourse focuses primarily on carbon sequestration and the reduction of greenhouse gas emissions, this report introduces a critical additional strategy for climate stability: the restoration of Earth’s hydrological cooling system. For over 4 billion years, water has been responsible for approximately 95% of Earth’s heat dynamics through interlinked processes like evapotranspiration and condensation. Central to this system is the soil carbon sponge, a living, porous infrastructure of healthy soil that manages freshwater and enables the cooling processes essential for ecosystem function.

Currently, the planet faces a severe destabilisation of this water cycle, with 52% of agricultural land degraded globally and nearly one-third of U.S. soils experiencing erosion rates up to 10 times higher than natural formation. This degradation shifts the surface energy balance away from cooling latent heat flux, which consumes heat through evaporation, and toward sensible heat flux, which directly increases air temperature. In Europe alone, 60-70% of soils are considered unhealthy , contributing to intensified heatwaves and a loss of the “green water” moisture that fuels regional cooling.

The report emphasises that rebuilding the soil carbon sponge acts as a powerful climate regulator, as every 1% increase in soil organic matter allows a hectare of land to hold an additional 250,000 liters of water. This stored water sustains the vegetation necessary for continuous evapotranspiration, which exports roughly 80 W/m² of solar energy back into the atmosphere. Restoring this biological cooling force could potentially offset the 0.9 W/m² total energy imbalance causing global warming by re-establishing a cooling effect that is three times larger than the warming caused by human-induced greenhouse gases.

To achieve long-term stability, climate policy must prioritise the regeneration of soil structure across all land types to restore infiltration and water storage. Recommendations include minimising bare soil exposure through cover cropping and mulching to suppress infrared re-radiation , and protecting forest ecosystems that drive “small water cycles” to return moisture to the soil. By integrating land regeneration with emissions reductions, we can restore the roughly 3.0 W/m² of lost natural cooling and enable landscapes to function once again as self-regulating climate stabilizers.

Dhami, A. S.; Yu, L.; Rau, R.; Sridhar, P. (2026). The Soil Carbon Sponge:

Restoring Earth’s Hydrological Cooling System for Climate Stability.

Conscious Planet.

The full report can be viewed and downloaded here.

There is an archive copy of the available at The Soil Carbon Sponge: Restoring Earth’s Hydrological Cooling System for Climate Stability