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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 10/2016

01.05.2016 | Original Article

A comparison of the predicted vulnerability zones with the data based on hazard zones of landslide in the Kurseong hill subdivision, Darjeeling district, West Bengal, India

verfasst von: Sudip Kumar Bhattacharya

Erschienen in: Environmental Earth Sciences | Ausgabe 10/2016

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Abstract

Kurseong hill subdivision, being one of the three (Kurseong, Sadar and Kalingpong) subdivisions of the hilly portions of the Darjeeling district, West Bengal, India, is affected by severe landslide incidence in the rainy season every year. These landslides and related phenomena frequently create social and economic instability disrupting communication system, claiming property and even sometimes life. Curbing landslide threat, therefore, becomes very much essential over this area. Individual landslide treatments are seen to be taken up by the construction engineers and geo-technical experts almost every year from government level. But reoccurrence of landslides on the same spots or surrounding places clearly reveals that construction works and filling procedures (usually taken up) are not the adequate measures to heal up the problem unless the area is treated as zones of landslides than individual spots of landslide occurrences. Therefore, the assessment of spatial probability of landslide occurrence in various magnitudes in the form of landslide vulnerability zones becomes essential. This spatial probability should also be compared with temporal probability based on the data of landslide incidence of the area for justification of match or mismatch between the inference drawn from the diagnostic criteria based assessment of the possibility level of landslide occurrence and the reality of the landslide scenario in the light of historical perspective of the area. This comparison will finally help to achieve the predicted vulnerability zones of landslide with desirable accuracy to put forward for planning decision. Moreover, such predicted vulnerability zonation can be taken as a standard estimate to use in planning purpose for the areas where historical data of landslide incidences are inadequate or unavailable. With this view in mind, the present paper takes an attempt to verify and compare landslide vulnerability zones derived from Spatial Terrain Parameter Evaluation (STPE) and Anthropogenic Criteria Identification (ACI) methods with the landslide hazard zones prepared from historical data, i.e. landslide inventory of certain length of time. Careful observation reveals that different degrees of landslide vulnerability zones significantly correspond with the similar magnitudes of the landslide hazard zones determined by past occurrence data of landslides over this hill subdivision and therefore validate the predictability procedure of landslide vulnerability zonation. The accuracy performance of the landslide vulnerability zonation model has further been verified by the occurrence dataset of landslide events through receiver operating characteristic curve analysis where area under curve evaluation showed 81.77 % correctness.
Vorheriger Artikel The identification of precipitation amount effect with a water isotope-enabled threshold model in vadose zone: a case study in Ordos Plateau
Nächster Artikel Climate footprint in karst aquifers derived from time series and spatial data: the case of Orce–María (SE Spain)

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Literatur
Bathrellos GD, Kalivas DP, Skilodimou HD (2009) GIS-based landslide susceptibility mapping models applied to natural and urban planning in Trikala, Central Greece. Estud Geol 65(1):49–65CrossRef
Bathrellos GD, Gaki-Papanastassiou K, Skilodimou HD, Papanastassiou D, Chousianitis KG (2012) Potential suitability for urban planning and industry development using natural hazard maps and geological–geomorphological parameters. Environ Earth Sci 66:537–548CrossRef
Bathrellos GD, Gaki-Papanastassiou K, Skilodimou HD, Skianis GA, Chousianitis KG (2013) Assessment of rural community and agricultural development using geomorphological–geological factors and GIS in the Trikala prefecture (Central Greece). Stoch Environ Res Risk Assess 27:573–588CrossRef
Bhattacharya SK (1999) A constructive approach to landslides through susceptibility zoning and case study in the Rakti basin of the Eastern Himalaya. Trans Jpn Geomorphol Union Jpn 20(3):317–333
Bhattacharya SK (2002) Tindharia Cricket Colony landslide in Darjeeling hills—a comparative account, 1996 and 001. In: Basu S (ed) Hanging environmental scenario of the Indian subcontinent. ACB Publication, Calcutta, pp 400–405
Bhattacharya SK (2009) Effect of deforestation on rainfall and runoff over the Terai and adjacent Hills in the Darjeeling district, West Bengal, India. Geogr Rev India Kolkata 71(2):130–136
Bhattacharya SK (2011) A comparison between the climatic characteristics of the Terai plains and the adjacent hills in Darjeeling district, West Bengal, India. Geogr Thoughts N.B.U Siliguri 9:55–59
Bhattacharya SK (2012a) Zonation mapping techniques of the landslide hazard in Darjeeling Hills, West Bengal, India. Geo-Analyst 2(1):12–17
Bhattacharya SK (2012b) Landslide disaster perception of the AILA cyclone in the Darjeeling town, West Bengal, India. Int J Geomat Geosci 3(1):14–29CrossRef
Bhattacharya SK (2014) A calibration technique for better estimation of soil loss in the Terai and adjacent Hills of West Bengal, India. Res Forum Int J Soc Sci 2(3):1–6
Chalkias C, Ferentinou M, Polykretis C (2014) GIS-based landslide susceptibility mapping on the Peloponnese Peninsula, Greece. Geosciences 4:176–190CrossRef
Du Bois RA (1985) Natural hazards assessment of the coastal area of Saint Lucia. West Indies Organization of American States, Washington, DC
Ercanoglu M, Gokceoglu C (2004) Use of fuzzy relations to produce landslide susceptibility map of a landslide prone area (West Black Sea Region, Turkey). Eng Geol 75:229–250CrossRef
Fell R, Stapledon D, Macgregor P (2012) Landslides and geologic environments. In: Clague JJ, Stead D (eds) Landslides—types, mechanisms and modelling. Cambridge University Press, New York, pp 134–143CrossRef
Ghosh S (2011) Knowledge guided empirical prediction of landslide hazard. Ph.D. Dissertation, University of Twente, pp 7–9
Gokceoglu C, Aksoy H (1996) Landslide susceptibility mapping of the slopes in the residual soils of the Mengen region (Turkey) by deterministic stability analyses and image processing techniques. Eng Geol 44:147–161CrossRef
Govt. of India (2009) National disaster management guidelines: management of landslides and snow avalanches. National Disaster Management Authority, New Delhi
Grabs T, Seibert J, Bishop K, Laudon H (2009) Modeling spatial patterns of saturated areas: a comparison of the topographic wetness index and a dynamic distributed model. J Hydrol 373:15–23CrossRef
Jaboyedoff M, Couture R, Locat P (2009) Structural analysis of Turtle Mountain (Alberta) using digital elevation model: toward a progressive failure. Geomorphology 103:5–16CrossRef
Julien PY (2010) Erosion and sedimentation, 2nd edn. Cambridge University Press, Cambridge, pp 1–3CrossRef
Lee S, Min K (2001) Statistical analysis of landslide susceptibility at Yongin, Korea. Environ Geol 40:1095–1113CrossRef
Lee S, Choi J, Min K (2004) Probabilistic landslide hazard mapping using GIS and remote sensing data at Boun, Korea. Int J Remote Sens 25:2037–2052CrossRef
Liao T, Hu D, Li X, Chen Y (2011) Landslide vulnerability evaluation: a case study from Sichuan, China. In: 19th International conference on geoinformatics, pp 1–4
Luan TX, Shibayama M, Cannata M, Long NH (2010) Area informatics and TRIGRS model for study shallow landslide vulnerability assessment. A case study in Bavi area, Hanoi region, Vietnam. In: International symposium on geoinformatics for spatial infrastructure development in Earth and Allied Sciences
Moore ID, Grayson RB, Ladson AR (1991) Digital terrain modeling: a review of hydrological, geomorphological, and biological applications. Hydrol Process 5:3–30CrossRef
Moore ID, Gesseler PE, Nielsen GA, Peterson GA (1993) Soil attribute prediction using terrain analysis. Soil Sci Soc Am 57:443–452CrossRef
Mukhopadhyay BP, Roy S, Chaudhuri S, Mitra S (2012) Influence of geological parameters on landslide vulnerability zonation of Darjeeling town, in Eastern Himalayas. Asian J Environ Disaster Manag 4(2):27–46CrossRef
Pandey A et al (2008) Landslide hazard zonation using Remote Sensing and GIS: a case study of Dikrong river basin, Arunachal Pradesh, India. Environ Geol 54(15):17–1529
Papadopoulou-Vrynioti K, Bathrellos GD, Skilodimou HD, Kaviris G, Makropoulos K (2013) Karst collapse susceptibility mapping using seismic hazard in a rapid urban growing area. Eng Geol 158:77–88CrossRef
Pourghasemi HR, Pradhan B, Gokceoglu C, Moezzi KD (2012) Landslide susceptibility mapping using a spatial multi criteria evaluation model at Haraz Watershed, Iran. In: Pradhan B, Buchroithner M (eds) Terrigenous mass movements: detection, modelling, early warning and mitigation using geoinformation technology, vol 8(2). Springer, Berlin, pp 23–49
Powde MB, Saha SS (1976) Geology of the Darjeeling Himalayas. In: Geological Survey of India miscellaneous publication, vol 41, pp 50–55
Rollerson T, Millard T, Thomson B (2002) Using terrain attributes to predict post-logging landslide likelihood on southwestern Vancouver Island. Forest Research Technical Report. TR-015 Geomorphology. Forest Service, BC, pp 1–15
Rozos D, Bathrellos GD, Skillodimou HD (2011) Comparison of the implementation of rock engineering system and analytic hierarchy process methods, upon landslide susceptibility mapping, using GIS: a case study from the Eastern Achaia County of Peloponnesus, Greece. Environ Earth Sci 63:49–63CrossRef
Rozos D, Skilodimou HD, Loupasakis C, Bathrellos DG (2013) Application of the revised universal soil loss equation model on landslide prevention. An example from N. Euboea (Evia) Island, Greece. Environ Earth Sci 70:3255–3266CrossRef
Saha AK, Gupta RP, Sarkar I, Arora MK, Csaplovics E (2005) An approach for GIS-based statistical landslide susceptibility zonation with a case study in the Himalayas. Landslides 2:61–69CrossRef
Sharma LP, Patel N, Ghose MK, Debnath P (2011) Landslide vulnerability assessment and zonation through ranking of causative parameters based on landslide density-derived statistical indicators. Geocarto Int 26(6):491–504CrossRef
Van Westen CJ, Bonilla JBA (1990) Mountain hazard analysis using PC-based GIS. In: 6th IAEG Congress, vol 1. Balkema, Rotterdam, pp 265–271
van Westen CJ, van Asch TWJ, Soeters R (2006) Landslide hazard and risk zonation-why is it still so difficult? Bull Eng Geol Environ 65:167–184CrossRef
Yeşilnacar E, Topal T (2005) Landslide Susceptibility Mapping: comparison between logistic regression and neural networks in a medium scale study, Hendek region (TURKEY). Eng Geol 79(3–4):51–266
Youssef AM, Maerz NH (2013) Overview of some geological hazards in the Saudi Arabia. Environ Earth Sci 70(7):3115–3130CrossRef
Zweig MH, Campbell G (1993) Receiver-operating characteristics (ROC) plots. Clin Chem 39:561–577
Metadaten
Titel
A comparison of the predicted vulnerability zones with the data based on hazard zones of landslide in the Kurseong hill subdivision, Darjeeling district, West Bengal, India
verfasst von
Sudip Kumar Bhattacharya
Publikationsdatum
01.05.2016
Verlag
Springer Berlin Heidelberg
Erschienen in
Environmental Earth Sciences / Ausgabe 10/2016
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-016-5729-8

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