Author Details

Scroll

Refine your search

Collections

Basic & Applied Science Collection

Co-Authors

Journals

Current Science

Year

Authors

A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All

Mishra, V. D.

Observations of Snow-Meteorological Parameters in Gangotri Glacier Region

Abstract Views :219 | PDF Views:95

Authors

H. S. Gusain ¹, Manish Kala ¹, Ashwagosha Ganju ¹, V. D. Mishra ¹, Snehmani ¹

Affiliations
1 Snow and Avalanche Study Establishment, Research and Development Centre, Chandigarh 160 036, IN

Source

Current Science, Vol 109, No 11 (2015), Pagination: 2116-2120

Abstract

In this communication analysis of the snow-meteorological parameters recorded in the Gangotri glacier region has been presented. Maximum temperature, minimum temperature, snowfall, snow cover thickness, incoming shortwave radiation flux, reflected shortwave radiation flux and albedo have been recorded at 'Bhojbasa' observation station. Meteorological data of 13 years from 2000 to 2012 have been presented for annual and seasonal variations in temperature, snowfall and snow cover thickness. Winter, premonsoon, monsoon and post-monsoon data have been considered for analysis. Annual mean maximum and minimum temperature are 11.1 ± 0.7°C and -2.3 ± 0.4°C respectively. Mean values of these parameters obtained for winter season are 3.0 ± 1.0°C and -10.4 ± 1.3°C respectively. Mean annual snowfall amount is 257.5 ± 81.6 cm and maximum snow cover thickness varies from 42 to 205 cm for different years. Incoming shortwave radiation flux and reflected shortwave radiation flux have been recorded using pyranometer sensor mounted on automatic weather station, and data for 2012 and 2013 are presented. Incoming shortwave radiation flux and total atmospheric transmissivity have been estimated. Mean annual atmospheric transmissivity is 0.37 at the observation location. Mean seasonal albedo for winter season is observed to be quite high compared to other seasons. Maximum and minimum temperature reveal an increase of 0.9°C and 0.05°C respectively, during the decade. Annual snowfall amount reveals a decrease of 37 cm in the decade. The observed temperature and snowfall patterns during the past 13 years, at the present study location, indicate that trends in Central Himalaya may be in accordance with the observed trends in the Western Himalaya.

Keywords

Albedo, Glacier, Snowfall, Snow Cover, Temperature.

Full Text

References

Bolch, T. et al., The state and fate of Himalayan glaciers. Science, 2012, 336, 310–314.

Bahuguna, I. M. et al., Are the Himalayan glaciers retreating? Curr. Sci., 2014, 106, 1008–1013.

Bhambri, R., Bolch, T. and Chaujar, R. K., Frontal recession of Gangotri Glacier, Garhwal Himalayas, from 1965 to 2006, measured through high-resolution remote sensing data. Curr. Sci., 2012, 102, 489–494.

Saraswat, P., Syed, T. H., Famiglietti, J. S., Fielding, E. J., Crippen, R. and Gupta, N., Recent changes in the snout position and surface velocity of Gangotri glacier observed from space. Int. J. Remote Sensing, 2013, 34:24, 8653–8668.

Kulkarni, A. V. and Karyakarte, Y., Observed changes in Himalayan glaciers. Curr. Sci., 2014, 106, 237–244.

Gantayat, P., Kulkarni, A. V. and Srinivasan, J., Estimation of ice thickness using surface velocities and slope: case study at Gangotri Glacier India. J. Glaciol., 2014, 60, 277–282.

Negi, H. S., Thakur, N. K., Ganju, A. and Snehmani, Monitoring of Gangotri glacier using remote sensing and ground observations. J. Earth Syst. Sci., 2012, 121, 855–866.

Shrestha, A. B., Wake, C. P., Mayewski, P. A. and Dibb, J. E., Maximum temperature trends in the Himalaya and its vicinity: an analysis based on temperature records from Nepal for the period 1971–94. J. Climate, 1999, 12, 2775–2786.

Dimri, A. P. and Dash, S. K., Winter temperature and precipitation trends in the Siachen Glacier. Curr. Sci., 2010, 98, 1620–1625.

Gusain, H. S., Chand, D., Thakur, N., Singh, A. and Ganju, A., Snow avalanche climatology of Indian Western Himalaya. In International Symposium on Snow and Avalanches, Manali, 6–10 April 2009.

Gusain, H. S., Mishra, V. D. and Arora, M. K., A four year record of the meteorological parameters, radiative and turbulent energy fluxes at the edge of the East Antarctic ice sheet, close to Schirmacher Oasis, Antarctic Science, 2014, 26(1), 93–103.

Dimri, A. P., Niyogi, D., Barros, A. P., Ridley, J., Mohanty, U. C., Yasunari, T. and Sikka, D. R., Western disturbances: a review. Rev. Geophys., 2015, 53, doi:10.1002/2014RG000460.

Dimri, A. P., Relationship between ENSO phases with Northwest India winter precipitation. Int. J. Climatol., 2012, doi:10.1002/ joc.3559.

Dimri, A. P. and Dash, S. K., Winter climatic trends in the western Himalaya. Climate Change, 2012, 111, 775–800.

Gusain, H. S., Mishra, V. D. and Bhutiyani, M. R., Winter temperature and snowfall trends in the cryospheric region of northwest Himalaya. Mausam, 2014, 65(3), 425–432.

Shekhar, M., Chand, H., Kumar, S., Srinivasan, K. and Ganju, A., Climate change studies over western Himalayan region. Ann. Glaciol., 2010, 51, 105.

Study of a Snow Avalanche Accident Along Chowkibal–Tangdhar Road in Kupwara District, Jammu and Kashmir, India

Abstract Views :260 | PDF Views:74

Authors

H. S. Gusain ¹, V. D. Mishra ¹, D. K. Singh ¹

Affiliations
1 Snow and Avalanche Study Establishment, Sector 37A, Chandigarh 160036,, IN

Source

Current Science, Vol 115, No 5 (2018), Pagination: 969-972

Abstract

An avalanche accident was occurred on 5 January 2018 on Chowkibal–Tangdhar road in Kupwara district, Jammu and Kashmir about 6 km from Chowkibal village. One light passenger vehicle was swept away in the avalanche and 10 persons lost their lives. In this communication, we study the cause of avalanche accident and simulate the snow avalanche flow using Rapid Mass MovementS model. Total snow depth recorded at the nearest observation location from the accident site was 31 cm and fresh snow of the storm was 24 cm. Avalanche condition on slope was building up and the Snow and Avalanche Study Establishment issued an avalanche warning of ‘Low Danger’ for the Chokibal–Tangdhar road axis. Maximum thickness of avalanche debris on road was observed to be 3.0 m. Flow simulation showed maximum velocity of avalanche to be ~25 ms^–1, maximum impact pressure ~9.39 × 10⁴ kg m^–1 s^–2 and maximum height of avalanche flow ~3.0 m.

Keywords

Avalanche Accident, Mountainous Terrain, Snow Storm.

Full Text

References

McClung, D. and Schaerer, P., The Avalanche Handbook, The Mountaineers Books, Seattle, WA, USA, 1993.

McClung, D. M., Avalanche character and fatalities in the high mountains of Asia. Ann. Glaciol., 2016, 57(71), 114–118.

Ganju, A., Thakur, N. K. and Rana, V., Characteristics of avalanche accidents in western Himalayan region, India. In Proceedings of the International Snow Science Workshop, Penticton, B.C., Canada, 29 September–4 October 2002, pp. 200–207.

Gusain, H. S., Chand, D., Thakur, N., Singh, A. and Ganju, A., Snow avalanche climatology of Indian Western Himalaya. In International Symposium on Snow and Avalanches, Manali, 6–10 April 2009.

Singh, A. and Ganju, A., A supplement to neares-neighbour method for avalanche forecasting. Cold Reg. Sci. Technol., 2004, 39, 105–113.

Singh, A., Srinivasan, K. and Ganju, A., Avalanche forecast using numerical weather prediction in Indian Himalaya. Cold Reg. Sci. Technol., 2005, 43, 83–92.

Joshi, J. C. and Srivastava, S., A Hidden Markov model for avalanche forecasting on Chowkibal–Tangdhar road axis in Indian Himalayas. J. Earth Syst. Sci., 2014, 123(8), 1771–1779.

Joshi, J. C. and Ganju, A., Avalanche warning on Chowkibal– Tangdhar axis (J&K): a hybrid approach. Curr. Sci., 2006, 91(11), 1558.

Gusain, H. S., Mishra, V. D., Arora, M. K., Mamgain, S. and Singh, D. K., Operational algorithm for generation of snow depth maps from discrete data in Indian Western Himalaya. Cold Reg. Sci. Technol., 2016, 126, 22–29.

Buhler, Y., Kumar, S., Veitinger, J., Christen, M., Stoffel, A. and Snehmani, Automated identification of potential snow avalanche release areas based on digital elevation models. Nat. Hazards Earth Syst. Sci., 2013, 13, 1321–1335.

Christen, M., Kowalski, J. and Bartelt, P., RAMMS: numerical simulation of dense snow avalanches in three-dimensional terrain. Cold Reg. Sci. Technol., 2010, 63, 1–14.

Development of Avalanche Information System using Remote Sensing and GIS Technology in the Indian Karakoram Himalaya

Abstract Views :245 | PDF Views:83

Authors

H. S. Gusain ¹, H. S. Negi ¹, Sudhir Dhamija ¹, V. D. Mishra ¹, Snehmani ¹

Affiliations
1 Snow and Avalanche Study Establishment, Sector 37A, Chandigarh 160 036, IN

Source

Current Science, Vol 117, No 1 (2019), Pagination: 104-109

Abstract

Snow avalanches pose severe threat to lives and property in snow-bound regions of the Western Himalaya. The Karakoram Range in Western Himalaya has the highest mean elevation and is the most glaciated region compared to other ranges. Snowfall in this range is frequent even during summer season. Snow accumulation on mountain slopes results into frequent snow avalanches and several lives have been lost due to snow avalanches in the past. In this communication we discuss about the development of avalanche information system using remote sensing and geographic information system (GIS) technology for the Indian Karakoram Himalaya. High spatial resolution (0.5 m) PLEIADES satellite images and digital elevation model (DEM) of ASTER GDEM V2 (30 m) and Cartosat (10 m) have been used here. Terrain parameters, e.g. slope, aspect, elevation, etc. have been derived using DEM. Sites in avalanche-prone areas have been identified using terrain parameters and snowfall information. Villages in the region, camp locations of borderguarding personnel, pedestrian routes followed by villagers and border-guarding personnel, avalanche sites along pedestrian routes, etc. have been digitized using appropriate GIS vector features, e.g. point, line and polygons. Past avalanche accidents along pedestrian routes, past avalanche occurrences, climatology of the region, etc. have been mapped in GIS environment. Remote sensing and GIS technology proved to be useful for the development of avalanche information system in digital form. The system is being used for avalanche forecasting and mitigation of avalanche hazard in the Indian Karakoram Himalaya.

Keywords

Avalanches, Geographic Information System, Remote Sensing, Snowfall.

Full Text

References

Sharma, S. S. and Ganju, A., Complexities of avalanche forecasting in Western Himalaya: an overview. Cold Reg. Sci. Technol., 2000, 31, 95–102.

Gusain, H. S., Mishra, V. D., Arora, M. K., Shailesh, M. and Singh, D. K., Operational algorithm for generation of snow depth maps from discrete data in Indian Western Himalaya. Cold Reg. Sci. Technol., 2016, 126, 22–29.

McClung, D. M., Avalanche character and fatalities in the high mountains of Asia. Ann. Glaciol., 2016, 57(71), 114–118.

Ganju, A., Thakur, N. K. and Rana, V., Characteristics of avalanche accidents in western Himalayan region, India. In Proceedings of the International Snow Science Workshop, Penticton, B.C., Canada, 29 September–4 October 2002, pp. 200–207.

Singh, D. K., Gusain, H. S., Mishra, V. D. and Gupta, N., Snow cover variability in North-West Himalaya during last decade. Arab. J. Geosci., 2018, 11, 579.

Eckerstorfer, M., Bühler, Y., Frauenfelder, R. and Malnes, E., Remote sensing of snow avalanches: recent advances, potential and limitations. Cold Reg. Sci. Technol., 2016, 121, 126–140.

Buhler, Y., Huni, A., Christen, M., Meister, R. and Kellenberger, T., Automated detection and mapping of avalanche deposits using airborne optical remote sensing data. Cold Reg. Sci. Technol., 2009, 57, 99–106.

Christen, M., Kowalski, J. and Bartelt, P., RAMMS: Numerical simulation of dense snow avalanches in three-dimensional terrain. Cold Reg. Sci. Technol., 2010, 63, 1–14.

Gusain, H. S., Mishra, V. D. and Singh, D. K., Study of a snow avalanche accident along Chowkibal–Tangdhar road in Kupwara district, Jammu and Kashmir, India. Curr. Sci., 2018, 115(5), 969– 972.

Biskupič, M. and Barka, I., Spatial modelling of snow avalanche run-outs using GIS. Symposium GIS, Ostrava, Czech Republic, 24–27 January 2010.

Bourova, E., Maldonado, E., Leroy, J.-B., Alouani, R., Eckert, N., Bonnefoy-Demongeot, M. and Deschatres, M., A new web-based system to improve the monitoring of snow avalanche hazard in France. Nat. Hazards Earth Syst. Sci., 2016, 16, 1205–1216.

Delparte, D., Jamieson, B. and Waters, N., Statistical runout modeling of snow avalanches using GIS in Glacier National Park, Canada. Cold Reg. Sci. Technol., 2008, 54, 183–192.

Omirzhanova, Zh. T., Urazaliev, A. S. and Aimenov, A. T., GIS for predicting the avalanche zones in the mountain regions of Kazakhstan. Int. Arch. Photogramm. Remote Sensing Spat. Inf. Sci., 2015, XL-2/W4, 39–44.

Dewali, S. K., Joshi, J. C., Ganju, A. and Snehmani, A GPS-based real-time avalanche path warning and navigation system. Geomat. Nat. Hazards Risk, 2014, 5(1), 56–80.

Kumar, S., Srivastava, P. K. and Snehmani, GIS-based MCDAAHP modelling for avalanche susceptibility mapping of Nubra Valley region, Indian Himalaya. Geocarto Int., 2017, 32(11), 1254–1267.

Singh, D. K., Mishra, V. D., Gusain, H. S., Gupta, N. and Singh, A. K., Geo-spatial modeling for automated demarcation of snow avalanche hazard areas using Landsat-8 satellite images and in situ data. J. Indian Soc. Remote Sensing, 2019; doi.org/10.1007/s12524-018-00936-w

Haegeli, P., Obad, J., Harrison, B., Murray, B., Engblom, J. and Neufeld, J., InfoexTM 3.0 – advancing the data analysis capabilities of Canada’s diverse avalanche community. In Proceedings of the International Snow Science Workshop, Banff, Alberta, Canada, 29 September–3 October 2014, pp. 910–917.

Akiyama, K. and Ikeda, S., Features of avalanches based on aerial photograph interpretation in Japan. In Proceedings of the International Snow Science Workshop, Grenoble, France, 7–11 October 2013, pp. 707–714.

Debernardi, A. and Segor, V., The avalanche cadaster of the Valle d’Aosta Region (NW Italian Alps: the new born web portal (http://catastovalanghe.partout.it/). In Proceedings of the International Snow Science Workshop, Grenoble, France, 7–11 October 2013, pp. 446–450.

Ruesch, M., Egloff, A., Gerber, M., Weiss, G. and Winkler, K., The software behind the interactive display of the Swiss avalanche bulletin. In Proceedings of the International Snow Science Workshop, Grenoble, France, 7–11 October 2013, pp. 406–412.

Jaedicke, C., Syre, E. and Sverdrup-Thygeson, K., GIS-aided avalanche warning in Norway. Comput. Geosci., 2014, 66, 31–39.

Ganju, A. and Dimri, A. P., Prevention and mitigation of avalanche disasters in Western Himalayan Region. Nat. Hazards, 2004, 31, 357–371.

Singh, A., Srinivasan, K. and Ganju, A., Avalanche forecast using numerical weather prediction in Indian Himalaya. Cold Reg. Sci. Technol., 2005, 43, 83–92

Joshi, J. C. and Ganju, A., Avalanche warning on Chowkibal– Tangdhar axis (J&K): a hybrid approach. Curr. Sci., 2006, 91(11), 1558

Joshi, J. C. and Srivastava, S., A hidden Markov model for avalanche forecasting on Chowkibal–Tangdhar road axis in Indian Himalayas. J. Earth Syst. Sci., 2014, 123(8), 1771–1779.

McClung, D. and Schaerer, P., The Avalanche Handbook, The Mountaineers Books, Seattle, WA, USA, 1993.

Username
Password
Remember me