Influence of relative sea-level rise, meteoritic water infiltration and rock weathering on giant volcanic landslides: theory and real cases

TL;DR

This paper investigates the causes of giant volcanic landslides, focusing on the roles of sea-level rise, meteoritic water infiltration, and rock weathering, using modeling and case studies to distinguish their effects.

Contribution

It introduces a modeling approach to differentiate the impacts of sea-level change and meteoritic water infiltration on triggering landslides in volcanic regions.

Findings

Meteoritic water infiltration can be distinguished from sea-level rise effects based on landslide timing and climate signals.

Sea-level variations influence pore pressure and magma chamber pressure, affecting slope stability.

Weathered volcanic rocks with low friction angles contribute to landslide susceptibility.

Abstract

Recent studies have shown that giant landslides seem to be correlated with climatic variations. Nevertheless, the precise processes that are involved in this phenomenon need to be better constrained. In this study, the causes of giant landslides are investigated using a modeling approach. Here, we show that the effect of meteoritic water infiltration could be discriminated from that of sea-level rise on triggering paleolandslides. It is possible to identify the cause of coastal paleolandslides based on the age of occurrence and comparison with climatic signals when glacial maxima are more humid than during interglacial times, as in Polynesia and East Equatorial Africa, but not in other cases (Caribbean, Indonesia). The role of pore pressure variations and sea-water loading variations has been discussed. The interaction between the relative sea-level rise, preexisting relief and deep weak structure due to the presence of highly weathered lavas may trigger the conditions for a large landslide. Highly weathered lavas have very low friction angles at depth in volcanic islands. When volcanoes are still actives, pressure variation of the magma chamber caused by sea-level lowering is expected to play a significant role in destabilization of the relief. Competing processes in real cases cause difficulties to discriminate between these processes.