The Landslide Hazard Chain in the Tapovan of the Himalayas on 7 February 2021

Jiang, Ruisong; Zhang, Li Min; Peng, Dalei; He, Xin; He, Jian

doi:10.1029/2021gl093723

Cited by 34 publications

(17 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Therefore, for SF1, we opted for the variable friction values, which are automatically estimated by RAMMS, based on DTM-derived parameters (slope angle, altitude, and curvature), and we further provided forest information and the global parameters of the return period and avalanche volume. In case of SF2, the debris flow module of RAMMS needed to be initialised through a carefully selected combination of µ and ε, calibrated using the documented [21][22][23][24] timeand flow-related details of the event. This calibration was achieved through the observed runout extent on the post-disaster satellite imagery and the reported debris flow zones, flow heights, and velocities [21][22][23][24].…”

Section: Rapid Mass Movement Simulation (Ramms)mentioning

confidence: 99%

“…In case of SF2, the debris flow module of RAMMS needed to be initialised through a carefully selected combination of µ and ε, calibrated using the documented [21][22][23][24] timeand flow-related details of the event. This calibration was achieved through the observed runout extent on the post-disaster satellite imagery and the reported debris flow zones, flow heights, and velocities [21][22][23][24]. Thus, the model was precisely calibrated through extensive iterations to define the optimal friction values of µ and ε as 0.13 and 200 ms −2 , respectively.…”

Section: Rapid Mass Movement Simulation (Ramms)mentioning

confidence: 99%

“…A study [21] provided a detailed overview of the 7 February 2021 avalanche hazard cascade and modelled this event to be consisting of 80% rock and 20% ice volume, generating a total avalanche volume of ~27 × 10 6 m 3 . Two more studies [22,23] also adopted similar approaches to put a volumetric constraint on the 7 February 2021 event and described the possible chain of events that led to the extensive destruction. Another recent study [24] used satellite datasets to investigate and comprehend the possible causes for progressive destabilisation at the ice-rock interface.…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, we intend to supplement these published studies (e.g., [21][22][23][24]) by focusing on the pre-event and during-event cascading flow characteristics using multi-temporal satellite datasets and robust rock-ice avalanche modelling approaches. We focus on quantifying and discussing the mechanical characteristics (momentum, pressure, and shear stress) of this mass movement leading to its translation into an enormous debris flow.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Reconstruction and Characterisation of Past and the Most Recent Slope Failure Events at the 2021 Rock-Ice Avalanche Site in Chamoli, Indian Himalaya

Bhardwaj

Sam

2022

Remote Sensing

View full text Add to dashboard Cite

Frequent ice avalanche events are being reported across the globe in recent years. On the 7 February 2021, a flash flood triggered by a rock-ice avalanche with an unusually long runout distance, caused significant damage of life and property in the Tapovan region of the Indian Himalaya. Using multi-temporal satellite datasets, digital terrain models (DTMs) and simulations, here we report the pre-event and during-event flow characteristics of two large-scale avalanches within a 5-year interval at the slope failure site. Prior to both the events, we observed short-term and long-term changes in surface velocity (SV) with maximum SVs increasing up to over 5 times the normal values. We further simulated the events to understand their mechanical characteristics leading to long runouts. In addition to its massive volume, the extraordinary magnitude of the 2021 event can partly be attributed to the possible remobilisation and entrainment of the colluvial deposits from previous ice and snow avalanches. The anomalous SVs should be explored further for their suitability as a possible remotely observable precursor of ice avalanches from hanging glaciers. This sequence of events highlights that there is a need to take into account the antecedent conditions, while making a holistic assessment of the hazard.

show abstract

Section: Rapid Mass Movement Simulation (Ramms)mentioning

confidence: 99%

Section: Rapid Mass Movement Simulation (Ramms)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Reconstruction and Characterisation of Past and the Most Recent Slope Failure Events at the 2021 Rock-Ice Avalanche Site in Chamoli, Indian Himalaya

Bhardwaj

Sam

2022

Remote Sensing

View full text Add to dashboard Cite

show abstract

“…Geologically, the area of the rock-ice avalanche hosts central Himalayan crystalline rocks of meta-sedimentary origin [56]. Predominant rock types in this area are gneiss, kyanite-schist, quartzite, calc-silicate, marble, migmatite-gneiss, and quartz-mica schists from the Proterozoic age [57][58][59]. The elevation range of the rockslide body is about 5600 masl, and the slope angle of the sliding body just before the event was about 40 • [54].…”

Section: Climatic and Physical Characteristics Of The Study Regionmentioning

confidence: 99%

7 February Chamoli (Uttarakhand, India) Rock-Ice Avalanche Disaster: Model-Simulated Prevailing Meteorological Conditions

2022

View full text Add to dashboard Cite

The present study aims to analyze the high-resolution model-simulated meteorological conditions during the Chamoli rock-ice avalanche event, which occurred on 7 February 2021 in the Chamoli district of Uttarakhand, India (30.37° N, 79.73° E). The Weather Research and Forecasting (WRF) model is used to simulate the spatiotemporal distribution of meteorological variables pre- and post-event. The numerical simulations are carried out over two fine resolution nested model domains covering the Uttarakhand region over a period of 2 weeks (2 February to 13 February 2021). The model-simulated meteorological variables, e.g., air temperature, surface temperature, turbulent heat flux, radiative fluxes, heat and momentum transfer coefficients, specific humidity and upper wind patterns, were found to show significant departures from their usual patterns starting from 72 h until a few hours before the rock-ice avalanche event. The average 2 m air and surface temperatures near the avalanche site during the 48 h before the event were found to be much lower than the average temperatures post-event. In-situ observations and the ERA5-Land dataset also confirm these findings. The total turbulent heat flux mostly remained downward (negative) in the 72 h before the event and was found to have an exceptionally large negative value a few hours before the rock-ice avalanche event. The model-simulated rainfall and Global Precipitation Measurement (GPM, IMERG)-derived rainfall suggest that the part of the Himalayan region falling in the simulation domain received a significant amount of rainfall on 4 February, around 48 h prior to the event, while the rest of the days pre- and post-event were mostly dry. The results presented here might be helpful in further studies to identify the possible trigger factors of this event.

show abstract

Seismic and radon signatures: A multiparametric approach to monitor surface dynamics of a hazardous 2021 rock–ice avalanche, Chamoli Himalaya

Tiwari,

Sain,

Tiwari

et al. 2024

Earth Surf Processes Landf

View full text Add to dashboard Cite

The observation of precursory signals of the 2021 Chamoli rock–ice avalanche provides an opportunity to investigate the multidisciplinary analysis approach of rock failure. On 7 February 2021, a huge rock–ice mass detached from the Raunthi peak at Chamoli district in Uttarakhand, India. The tragic catastrophe resulted in more than 200 deaths and significant economic losses. Here, we analyse radon concentration and seismic signals to characterise the potential precursory anomalies prior to the detachment. Continuous peaks of radon anomalies were observed from the afternoon of 5 to 7 February and decreased suddenly after the event, while a cumulative number of seismic tremors and amplitude variations are more intensified ~2.30 h before the main event, indicating a static to dynamic phase change within the weak zone. This study not only characterises abnormal signals but also models the rock failure mechanisms. The analysis unveils three time‐dependent nucleation phases, physical mechanisms of signal generation and a complete scenario of physical factors that affected the degree of criticality of slope failure. The results of this study suggest gradual progression of rock cracks/joints, subsequent material creep and slip advancement acceleration preceded the final failure. Furthermore, the study highlights the importance of an early warning system to mitigate the impact of events like the 2021 Chamoli rock–ice avalanche.

show abstract

The Landslide Hazard Chain in the Tapovan of the Himalayas on 7 February 2021

Cited by 34 publications

References 33 publications

Reconstruction and Characterisation of Past and the Most Recent Slope Failure Events at the 2021 Rock-Ice Avalanche Site in Chamoli, Indian Himalaya

Reconstruction and Characterisation of Past and the Most Recent Slope Failure Events at the 2021 Rock-Ice Avalanche Site in Chamoli, Indian Himalaya

7 February Chamoli (Uttarakhand, India) Rock-Ice Avalanche Disaster: Model-Simulated Prevailing Meteorological Conditions

Seismic and radon signatures: A multiparametric approach to monitor surface dynamics of a hazardous 2021 rock–ice avalanche, Chamoli Himalaya

Contact Info

Product

Resources

About