Rainfall triggers more deep-seated landslides than Cascadia earthquakes in the Oregon Coast Range, USA

LaHusen, Sean Richard; Duvall, Alison R.; Booth, Adam M.; Grant, Alex; Mishkin, Benjamin; Montgomery, David R.; Struble, William; Roering, Joshua J.; Wartman, Joseph

doi:10.1126/sciadv.aba6790

Cited by 56 publications

(59 citation statements)

References 47 publications

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“…Large rockslides are major landscape modifiers in mountainous regions 1 and often induce secondary and cascading hazards, such as rockslide-induced impulse waves 2 or valley damming with subsequent outburst floods 3 . Documented rockslides are mostly triggered by heavy precipitation 4 , 5 or severe earthquakes 6 . Some prehistoric rockslides were of extraordinary size, and if similar events were to occur today they would have devastating impacts.…”

Section: Introductionmentioning

confidence: 99%

Seismic control of large prehistoric rockslides in the Eastern Alps

et al. 2021

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Large prehistoric rockslides tend to occur within spatio-temporal clusters suggesting a common trigger such as earthquake shaking or enhanced wet periods. Yet, trigger assessment remains equivocal due to the lack of conclusive observational evidence. Here, we use high-resolution lacustrine paleoseismology to evaluate the relation between past seismicity and a spatio-temporal cluster of large prehistoric rockslides in the Eastern Alps. Temporal and spatial coincidence of paleoseismic evidence with multiple rockslides at ~4.1 and ~3.0 ka BP reveals that severe earthquakes (local magnitude ML 5.5–6.5; epicentral intensity I0 VIII¼–X¾) have triggered these rockslides. A series of preceding severe earthquakes is likely to have progressively weakened these rock slopes towards critical state. These findings elucidate the role of seismicity in preparing and triggering large prehistoric rockslides in the European Alps, where rockslides and earthquakes typically occur in clusters. Such integration of multiple datasets in other formerly glaciated regions with low to moderate seismicity will improve our understanding of catastrophic rockslide drivers.

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Section: Introductionmentioning

confidence: 99%

Seismic control of large prehistoric rockslides in the Eastern Alps

et al. 2021

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“…In attempts to link OCR slope failures with known triggering mechanisms, most prior landslide dating has relied on 14 C dating of organic material collected from landslide deposits (e.g., Benda, 1990;LaHusen et al, 2020;Pierson et al, 2016;Reneau & Dietrich, 1991;Reneau et al, 1986). In addition, surface (topographic) roughness dating of landslides, where rougher (smoother) landslide deposits are younger (older), has been used to map and construct landslide age databases (Booth et al, 2009(Booth et al, , 2017LaHusen et al, 2016).…”

Section: Dating Landslide Damsmentioning

confidence: 99%

“…In addition, these new landslide ages Dams with numeric labels are those we date here and are numbered according to Table 1. Dams with alphabetic labels are dams with existing age control: A: Ayers Lake (1975 AD; Thrall et al, 1980), G: Gould Lake (1894 AD; Zybach, 2003), K: Klickitat Lake (winter 1751/52 AD; Struble et al, 2020), L: Loon Lake (∼1460 years BP; Baldwin, 1958), S: Sitkum (>3,000 years BP; LaHusen et al, 2020;Lane, 1987), T: Triangle Lake (>42000 years BP; Worona & Whitlock, 1995), W: Wasson Lake (winter 1819/20 AD; Struble et al, 2020). Black box corresponds to border of Figure 2.…”

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confidence: 99%

The Preservation of Climate‐Driven Landslide Dams in Western Oregon

et al. 2021

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“…In particular, it was observed that the fault rupture mechanism strongly influences the distribution of landslides, which are usually more abundant on the hanging wall in the case of reverse or normal faults (Sato et al, 2007) and present a symmetric distribution in the case of strike-slip faulting (Xu and Xu, 2014). In the case of co-seismic landslides related to earthquakes in subduction zones, very few data and inventories are available (LaHusen et al, 2020;Schulz et al, 2012;Serey et al, 2019;Wartman et al, 2013). Best examples are the landslides induced by the 2010 Chile megathrust earthquake (Serey et al, 2019) and by the 2011 Tohoku earthquake in Japan (Wartman et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Intermediate processes such as shallow landslides and debris flows are common in the case of an earthquake, but they are relatively poorly documented for past events. Debris flows, often called lahar in volcanic environments, are usually associated with eruptions that induce ice melt or snowmelt or with intense rainfalls occurring during intra-eruptive phases (e.g., Capra et al, 2018;Major et al, 2016;Manville et al, 2009). Few examples of long-runout debris flows triggered by earthquakes have been described on active volcanoes (Schuster et al, 1996;Scott et al, 2001).…”

Section: Introductionmentioning

confidence: 99%

Earthquake-induced debris flows at Popocatépetl Volcano, Mexico

Coviello

Capra²,

Norini

et al. 2021

Earth Surf. Dynam.

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Abstract. The 2017 Mw 7.1 Puebla–Morelos intraslab earthquake (depth: 57 km) severely hit Popocatépetl Volcano, located ∼ 70 km north of the epicenter. The seismic shaking triggered shallow landslides on the volcanic edifice, mobilizing slope material saturated by the 3 d antecedent rainfall. We produced a landslide map based on a semi-automatic classification of a 50 cm resolution optical image acquired 2 months after the earthquake. We identified hundreds of soil slips and three large debris flows for a total affected area of 3.8 km2. Landslide distribution appears controlled by the joint effect of slope material properties and topographic amplification. In most cases, the sliding surfaces correspond with discontinuities between pumice-fall and massive ash-fall deposits from late Holocene eruptions. The largest landslides occurred on the slopes of aligned ENE–WSW-trending ravines, on opposite sides of the volcano, roughly parallel to the regional maximum horizontal stress and to volcano-tectonic structural features. This suggests transient reactivation of local faults and extensional fractures as one of the mechanisms that weakened the volcanic edifice and promoted the largest slope failures. The material involved in the larger landslides transformed into three large debris flows due to liquefaction. These debris flows mobilized a total volume of about 106 m3 of material also including large wood, were highly viscous, and propagated up to 7.7 km from the initiation areas. We reconstructed this mass wasting cascade by means of field evidence, samples from both landslide scarps and deposits, and analysis of remotely sensed and rainfall data. Although subduction-related earthquakes are known to produce a smaller number of landslides than shallow crustal earthquakes, the processes described here show how an unusual intraslab earthquake can produce an exceptional impact on an active volcano. This scenario, not related to the magmatic activity of the volcano, should be considered in multi-hazard risk assessment at Popocatépetl and other active volcanoes located along volcanic arcs.

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Rainfall triggers more deep-seated landslides than Cascadia earthquakes in the Oregon Coast Range, USA

Cited by 56 publications

References 47 publications

Seismic control of large prehistoric rockslides in the Eastern Alps

Seismic control of large prehistoric rockslides in the Eastern Alps

The Preservation of Climate‐Driven Landslide Dams in Western Oregon

Earthquake-induced debris flows at Popocatépetl Volcano, Mexico

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