Deep critical zone controls on shallow landslides

Seulgi Moon; Giuseppe Formetta; Justin T. Higa; Riccardo Busti; Dino G. Bellugi; David G. Milledge; Brian A. Ebel; William E. Dietrich

doi:10.1073/pnas.2524542123

Deep critical zone controls on shallow landslides

Proceedings of the National Academy of Sciences

By: Seulgi Moon, Giuseppe Formetta, Justin T. Higa, Riccardo Busti, Dino G. Bellugi, David G. Milledge, Brian A. Ebel, and William E. Dietrich

https://doi.org/10.1073/pnas.2524542123

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Abstract

The deep critical zone (CZ) has long been recognized for its importance in influencing shallow landslides but was not considered feasible to include in slope stability models at the watershed scale. In this study, we demonstrate that simple approximations of the CZ in a fully coupled hydrologic and soil slope stability model can effectively capture the location, timing, and likely size of shallow landslides. To achieve this, we use coupled, process-based models that incorporate the effects of 1) deep CZ structures, 2) three-dimensional transient hydrology, and 3) multidimensional slope stability, calibrated with data from an intensively monitored field site. Our results show that the hydrologically active deep CZ guides groundwater flow, influencing where it drains from or exfiltrates to the soil mantle, producing distinct patterns of soil saturation and seepage forces at the soil-bedrock boundary. Deep conductive weathered critical zone drains the soil mantle, reducing the likelihood of destabilizing pore pressures, while the downslope thinning of the CZ forces groundwater to the surface. This creates localized instability and a tendency for similar-sized landslides across the landscape. In contrast, the absence of conductive weathered bedrock results in more widespread destabilizing pore pressures, leading to larger landslides and the likelihood of landslides earlier in a storm than in landscapes underlain by a deep CZ. Our findings suggest that first-order variations of deep CZ can provide physical explanations for variations observed in the susceptibility, magnitude, and timing of shallow landslides, and that CZ structure may be inferred from patterns and timing of landsliding.

Suggested Citation

Moon, S., Formetta, G., Higa, J.T., Busti, R., Bellugi, D.G., Milledge, D.G., Ebel, B., and Dietrich, W.E., 2026, Deep critical zone controls on shallow landslides: Proceedings of the National Academy of Sciences, v. 123, no. 12, e2524542123, 12 p., https://doi.org/10.1073/pnas.2524542123.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Deep critical zone controls on shallow landslides
Series title	Proceedings of the National Academy of Sciences
DOI	10.1073/pnas.2524542123
Volume	123
Issue	12
Publication Date	March 18, 2026
Year Published	2026
Language	English
Publisher	National Academy of Sciences
Contributing office(s)	WMA - Earth System Processes Division
Description	e2524542123, 12 p.