From sink to volcanic source: Unravelling missing terrestrial eruption records by characterization and high‐resolution chronology of lacustrine volcanic density flow deposits, Lake Inawashiro‐ko, Fukushima, Japan

Kataoka, Kyoko; Nagahashi, Yoshitaka

doi:10.1111/sed.12629

Cited by 14 publications

(4 citation statements)

References 110 publications

(174 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Sedimentologists interpreting stratigraphy in lacustrine or marine cores offshore of volcanic terrain would likely interpret a thick ‘event’ deposit as representing some tectonic or climatic disturbance, i.e., a major earthquake (Hill et al, 2022) or storm rainfall and flooding associated with a strong El Niño episode (Covault et al, 2010). Even if enough sediment cores were available to reveal that the deposit was spatially localized rather than extending along a continental margin (as expected from a megathrust earthquake or climatic disturbance), it would seem reasonable to attribute a thick volcaniclastic deposit to a large volcanic eruption (Kataoka & Nagahashi, 2019; Manville et al, 2009). It is unlikely that scientists interpreting the downstream sedimentary record would arrive at the interpretation of a rare, autogenic, stochastic watershed process involving a collapse of grade control and major regressive erosion.…”

Section: Discussionmentioning

confidence: 99%

Major fluvial erosion and a 500‐Mt sediment pulse triggered by lava‐dam failure, Río Coca, Ecuador

Barrera Crespo,

Espinoza Girón,

Bedoya

et al. 2024

Earth Surf Processes Landf

View full text Add to dashboard Cite

The failure of a 144‐m‐high lava‐dam waterfall on the Río Coca, Ecuador, in February 2020 initiated a catastrophic watershed reset—regressive erosion upstream and a massive sediment pulse downstream—as the river evolves towards a new equilibrium grade. The evolution of this river corridor after a sudden base‐level fall embodies the “complex response” concepts long understood through laboratory experiments, numerical modelling and smaller‐scale field studies, but that have not been observed in the field before on this scale. This paper presents geomorphic and geotechnical data to characterize the evolution of the Río Coca since 2020. In the three years after the lava‐dam failure, the erosion front migrated almost 13 km upstream along the mainstem river and triggered secondary headcuts that began migrating up tributaries. Erosion of the mainstem and tributary valleys generated a sediment pulse estimated to be 277 million m3 and ~500 million tonnes (Mt) over three years, depositing sediment tens of meters thick over tens of kilometres downstream from the former waterfall. This sediment pulse is one of the largest in modern times, comparable to the annual sediment load of a major continent‐draining river but with orders‐of‐magnitude greater sediment yield. Geomorphic adjustment of the Río Coca represents a highly unusual natural disaster threatening life, property, water quality, the regional economy, major infrastructure and energy security. However, this event also provides a rare opportunity to learn how a large autogenic watershed disturbance and recovery evolve, with important lessons for interpreting the sedimentary record of volcanic landscapes.

show abstract

Section: Discussionmentioning

confidence: 99%

Major fluvial erosion and a 500‐Mt sediment pulse triggered by lava‐dam failure, Río Coca, Ecuador

Barrera Crespo,

Espinoza Girón,

Bedoya

et al. 2024

Earth Surf Processes Landf

View full text Add to dashboard Cite

show abstract

“…Lahar deposits associated with magmatic pyroclastic eruptions include gravel and sand-sized particles (e.g., Pierson et al 1996) and can vary from matrix-rich (not clay-rich but silt-and sand-rich) to clast-rich, depending on the eruption style, size, and explosiveness (e.g., Mothes and Vallance 2015). In contrast, phreatic and magmatic hydrothermal activity through extant hydrothermal systems can produce clay-rich ejecta and hence clay-rich, syn-and post-eruptive lahars (Kataoka et al 2018;Kataoka and Nagahashi 2019). Also, gravitational collapse of hydrothermally altered parts of the volcanic edifice can produce clay-rich lahars (Vallance and Scott 1997;Vallance 2005).…”

Section: Flow Type Of the Predicted Lahars After The 2018 Phreatic Eruptionmentioning

confidence: 99%

Crisis hazard assessment for snow-related lahars from an unforeseen new vent eruption: the 2018 eruption of Kusatsu-Shirane volcano, Japan

Kataoka

Tsunematsu

Matsumoto

et al. 2021

Earth Planets Space

Self Cite

View full text Add to dashboard Cite

Two-thirds of the 111 active volcanoes in Japan are covered with snow for several months during winter and demonstrate high hazard and risk potentials associated with snow-related lahars during and after eruptions. On 23 January 2018, a sudden phreatic eruption occurred at the ski field on Kusatsu-Shirane (Mt. Motoshirane) volcano, Japan. This new vent eruption from the snow-clad pyroclastic cone required forecasting of future snow-related lahars and crisis hazards zonation of downslope areas including Kusatsu town, a popular tourist site for skiing and hot springs. In order to achieve a prompt hazard assessment for snow-related lahars, a multidisciplinary approach was carried out involving characterization of proximal tephra deposits, snow surveys, and numerical lahar flow simulations using the Titan2D model. To determine the input parameters for the flow model, the consideration of snow water equivalent (SWE) immediately after the eruption (on 29 January) and in the post-eruptive period (on 12 March), was significant. In the case of Kusatsu-Shirane volcano during the winter of 2018, linear relationships between altitude and SWE, obtained at different elevations, were used to estimate the snow volume around the new vents. Several scenarios incorporating snow and snowmelt (water), with or without the occurrence of a new eruption, were simulated for the prediction of future lahars. Three lahar scenarios were simulated, including A) rain-on-snow triggered, B) ice/snow slurry, and C) full snowmelt triggered by a new eruption, and indicated the flow paths (inundation areas) and travel distances. These were useful for lahar hazard zonation and identification of potential high-risk areas. Since the input parameters required for the Titan2D flow model can be relatively easily determined, the model was suitable for the 2018 eruption at Motoshirane where historical and geological lahar records are not available for calibration. The procedure used in the study will enable rapid lahar prediction and hazard zonation at snow-clad volcanoes. Further consideration for simulating a cohesive-type flow, which was predicted by the primary deposits containing large amounts of clay minerals and could not be expressed in the Titan2D flow model, is necessary.

show abstract

“…Mixed sediments vary in lithology, lithofacies and vertical succession, related to the varied transportation distances and environments. Kataoka and Nagahashi (2019) reconstructed the missing terrestrial eruption from the modern lacustrine records of volcanic flow deposits of Lake Inawashiro‐ko in Fukushima, Japan, manifesting a dispersal path from volcanic source to sink. Cas et al (2001) provided a case study of the Upper Devonian, Australia, demonstrating that the deposits in lakes are distinctive and useful for a systematic understanding of the behaviour of volcanic clasts and dispersal processes.…”

Section: Sediment Model Interpretationmentioning

confidence: 99%

Volcanism‐induced sedimentation and model: A case study of the Upper Jurassic‐Lower Cretaceous sediments in the Liuhe‐Tonghua Basin, NE China

et al. 2020

View full text Add to dashboard Cite

Understanding how the lacustrine environment adapts to volcanism and the relevant products is one of the key goals of volcaniclastic sedimentology. Mixed sediments can be deposited in lacustrine basins during the interaction between volcano and environment. This article is focus on the lithology, lithofacies, association, and sedimentary sequence of the Late Jurassic-Early Cretaceous mixed sediments from the Liuhe-Tonghua Basin, revealing the transportation-accumulation processes of volcanic materials from subaerial eruption into water or subaqueous eruption mingling with terrigenous clasts. Four kinds of mixed-sediment rocks are identified including tuffaceous sandstone, tuff-lapilli tuff, breccia-agglomerate/lava and tuff lava/lava, and six lithofacies associations are identified: (a) base surge and pyroclastic flow, interpreted as the middle-distal end of a mixed-fan delta; (b) base surge-pyroclastic flow and turbidite flow, interpreted as the distal end of a mixed-fan delta; (c) base surge-pyroclastic flow-turbidite flow and mud deposits, interpreted as a mixed subaqueous fan; (d) sand sheet of the base surge and mud deposits, interpreted as a deepwater region; (e) subaerial volcanic edifice, interpreted as a volcanic ventproximal slope; (f) subaqueous volcanic edifice, interpreted as a volcanic slope. These associations may exhibit different spatial occurrences and palaeogeographic distributions, representing the transition from a volcanic to a sedimentary environment in the source to sink system, and an ideal mixed sedimentation model is established based on these associations and relevant mud deposits. These associations also exhibit a typical volcanic-sedimentary sequence including terrigenous lowstand sediments in extensional settings and mixed volcanic and terrigenous transgressivehighstand sediments in trans-extensional settings. This article presents a case of volcaniclastic sedimentation (mixed sedimentation) of Cretaceous volcano-fault basin in Northeast China, which can provide a reference for the lacustrine volcaniclastic deposition in other similar genetic basins around the world.

show abstract

From sink to volcanic source: Unravelling missing terrestrial eruption records by characterization and high‐resolution chronology of lacustrine volcanic density flow deposits, Lake Inawashiro‐ko, Fukushima, Japan

Cited by 14 publications

References 110 publications

Major fluvial erosion and a 500‐Mt sediment pulse triggered by lava‐dam failure, Río Coca, Ecuador

Major fluvial erosion and a 500‐Mt sediment pulse triggered by lava‐dam failure, Río Coca, Ecuador

Crisis hazard assessment for snow-related lahars from an unforeseen new vent eruption: the 2018 eruption of Kusatsu-Shirane volcano, Japan

Volcanism‐induced sedimentation and model: A case study of the Upper Jurassic‐Lower Cretaceous sediments in the Liuhe‐Tonghua Basin, NE China

Contact Info

Product

Resources

About