Cause and Process Mechanism of Rockslide Triggered Flood Event in Rishiganga and Dhauliganga River Valleys, Chamoli, Uttarakhand, India Using Satellite Remote Sensing and in situ Observations

Pandey, Pratima; Chauhan, Prakash; Bhatt, C. M.; Thakur, Praveen K.; Kannaujia, Suresh; Dhote, Pankaj R.; Roy, Arijit; Kumar, Santosh; Chopra, Sumer; Bhardwaj, Ashutosh; Aggrawal, S. P.

doi:10.1007/s12524-021-01360-3

Cited by 61 publications

(25 citation statements)

References 21 publications

(16 reference statements)

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“…However, in response to the increase in annual average temperature, the permafrost is depleting in many regions globally, including the Himalaya. The thawing of permafrost can have diverse and widespread impacts on society, such as an increase in landslides and land degradation due to destabilization of slopes [6][7][8][9], ground subsidence [10][11][12], changes in subsurface hydrology [13][14][15], damage to infrastructure [16,17], and change in sediment load of rivers [18]. More importantly, as the permafrost thaws, it releases greenhouse gases from the stored soil organic carbon, which creates positive feedback and further amplifies the rate of rise in annual average temperature [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

“…The present study will serve as an analogue for future permafrost studies that will help in understanding the dynamics of permafrost in a changing environment and has implications for discerning the impacts of permafrost thawing on the evolution of potential natural hazards that may affect the high mountain communities. This becomes critical considering the higher rates of warming than the global averages [59][60][61][62] and increasing frequency of disasters in permafrost areas [9,63] observed in the Himalaya.…”

Section: Introductionmentioning

confidence: 99%

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Modelling Permafrost Distribution in Western Himalaya Using Remote Sensing and Field Observations

et al. 2021

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The presence and extent of permafrost in the Himalaya, which is a vital component of the cryosphere, remains severely under-researched with its future climatic-driven trajectory only partly understood and the future consequences on high-altitude ecosystem tentatively sketched out. Previous studies and available permafrost maps for the Himalaya relied primarily upon the modelled meteorological inputs to further model the likelihood of permafrost. Here, as a maiden attempt, we have quantified the distribution of permafrost at 30 m grid-resolution in the Western Himalaya using observations from multisource satellite datasets for estimating input parameters, namely temperature, potential incoming solar radiation (PISR), slope, aspect and land use, and cover. The results have been compared to previous studies and have been validated through field investigations and geomorphological proxies associated with permafrost presence. A large part of the study area is barren land (~69%) due to its extremely resistive climate condition with ~62% of the total area having a mean annual air temperature of (MAAT) <1 °C. There is a high inter-annual variability indicated by varying standard deviation (1–3 °C) associated with MAAT with low standard deviation in southern part of the study area indicating low variations in areas with high temperatures and vice-versa. The majority of the study area is northerly (~36%) and southerly (~38%) oriented, receiving PISR between 1 and 2.5 MW/m2. The analysis of permafrost distribution using biennial mean air temperature (BMAT) for 2002-04 to 2018-20 suggests that the ~25% of the total study area has continuous permafrost, ~35% has discontinuous permafrost, ~1.5% has sporadic permafrost, and ~39% has no permafrost presence. The temporal analysis of permafrost distribution indicates a significant decrease in the permafrost cover in general and discontinuous permafrost in particular, from 2002-04 to 2018-20, with a loss of around 3% for the total area (~8340.48 km2). The present study will serve as an analogue for future permafrost studies to help understand the permafrost dynamics associated with the effects of the recent abrupt rise in temperature and change in precipitation pattern in the region.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modelling Permafrost Distribution in Western Himalaya Using Remote Sensing and Field Observations

et al. 2021

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“…The flood caused more than 200 fatalities or missing individuals (Shugar et al, 2021). It was one of the most catastrophic geo-disasters on record in this region, and attracted wide attentions (Martha et al, 2021;Meena et al, 2021;Pandey et al, 2021;Rana et al, 2021;Shrestha et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

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

Jiang

Zhang

Peng

et al. 2021

Geophysical Research Letters

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On February 7, 2021, a catastrophic landslide occurred in Chamoli, India on the southern hills of the Himalayas (  30.37 N,  79.73 E). About 28 × 10 6 m 3 of landslide mass detached from the mountain face, entrained deposits in the valley and riverbed, and generated a huge debris flood along the Dhauliganga River. In this study, the geomorphological and volumetric characteristics of the disaster chain were interpreted from satellite images. The full process of the disaster chain and the erosion, deposition and flow discharge processes were reproduced using a cell-based analysis program, Erosion-Deposition Debris Flow Analysis (EDDA). The results indicate a peak flow discharge of the debris flood at Tapovan Hydropower Station of about 25,000-28,000 m 3 /s. The main erosion and deposition zones are distributed along the valley floor and the Dhauliganga River, respectively. This study serves as basis for understanding the disaster chain dynamics in high mountain areas.Plain Language Summary Catastrophic geo-disasters become more frequent in the Himalayan region due to the global climate change, and pose threats to the local residents and infrastructure. A large landslide happened in the Tapovan area in the south of the Himalayas on February 7, 2021, which triggered a large avalanche down the valley, entrained the deposits and river water, and evolved into a catastrophic debris flood in the Dhauliganga River, causing fatalities and severe damage to the local infrastructure. This study reconstructs the entire geo-disaster process, and reveals key characteristics including the landslide source, erosion and deposition features, and the transformation of hazard types. The outcome from this study helps understand and manage the risk of catastrophic geohazards in high mountain areas, especially in the Himalayas and other areas of the Tibetan Plateau. JIANG ET AL.

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“…The event took place in the Tapovan area of Joshimath in the Chamoli District of Uttarakhand, India on 7 February 2021 at 4:51 UTC [51][52][53]55] (Figure 1A,B). During this event, a massive rock and ice avalanche happened approximately 22 km upstream of Tapovan Hydropower Project, below Ronti peak in the Nanda Devi massif [51,53,55], which led to a sequence of events that resulted in the loss of many lives and the infrastructural damage of two major hydropower projects in the Rishiganga and Dhauliganaga valleys (Figure 1C).…”

Section: Event Descriptionmentioning

confidence: 99%

“…The triggering factors behind this rock-ice avalanche event could be unusual local meteorological conditions (temperatures, precipitation, winds speed and pattern, wind stress, radiative and turbulent fluxes, etc. ), climatic conditions (long-term changes in surface and air temperatures and precipitation patterns), and geological factors (extremely steep slope, destabilization of the rock due to the decreased ice cover, seismic activity) [28,[51][52][53][54].…”

Section: Introductionmentioning

confidence: 99%

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

2022

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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.

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Cause and Process Mechanism of Rockslide Triggered Flood Event in Rishiganga and Dhauliganga River Valleys, Chamoli, Uttarakhand, India Using Satellite Remote Sensing and in situ Observations

Cited by 61 publications

References 21 publications

Modelling Permafrost Distribution in Western Himalaya Using Remote Sensing and Field Observations

Modelling Permafrost Distribution in Western Himalaya Using Remote Sensing and Field Observations

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

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

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