Abstract
Landslides in the three studied basins of the Siwalik Hills are not random in distribution; they tend to cluster in certain areas implying the control of certain in situ factors or their combination. Landslide controlling in situ factors were reviewed and analyzed from maps, aerial photos and imageries using GIS. Chi square analysis was carried out to test the significance of landslide distribution vis-à-vis in situ factors. Slope gradient and relative relief were consistently significant in landslide distribution. Geology, dip-topography relation, land use and land cover, and vegetation conditions appeared important in landslide occurrence in all three basins either in terms of area or count in any two basins. Slope aspect and altitude tested significant for landslide occurrence in at least two basins. However, upslope flow contributing area, drainage density and distance to lineament were found insignificant in all three basins. In situ factors that tested significant in any two basins were used for landslide susceptibility analysis using a bivariate statistical approach. The distribution of landslides strongly correlates with susceptibility indices. With in situ factors, landslide susceptibility had good correlation with slope gradient and relative relief. Incorporating calculated factor weight values from one basin to the other two basins, proxy susceptibility index maps were also prepared. A moderate to good positive correlation appeared between them implying certain range of confidence for replicating the result for whole of the Siwalik Hills. Slope gradient and relative relief can be used as proxy indicators of landslide susceptible areas in the Siwalik Hills.
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References
Anbalagan D (1992) Landslide hazard evaluation and zonation mapping in mountainous terrain. Eng Geol 32:269–277
Ayalew L, Yamagishi H (2005) The application of GIS-based logistic regression for landslide susceptibility mapping in the Kakuda-Yahiko Mountains, Central Japan. Geomorphol 65:15–31
Bell FG (1998) Environmental geology: principles and practice. Wiley-Blackwell, NY
Beven KJ, Kirkby MJ (1979) A physically based variable contributing area model of basin hydrology. Hydrol Sci Bull 24:43–69
Boots BN, Gettis A (1988) Point pattern analysis. Sage University Scientific Geography Series no. 8. Sage Publications, Beverly Hills
Brabb EE (1995) The San Mateo County California GIS project for predicting the consequences of hazardous geologic processes. In: Carrara A, Guzzetti F (eds) Geographical information systems in assessing natural hazards. Kluwer Academic Publisher, Dordrecht, pp 299–334
Brenning A (2005) Spatial prediction models for landslide hazards: review, comparison and evaluation. Nat Hazards Earth Syst Sci 5:853–862
Brunsden D, Jones DKC (1972) Morphology of degraded landslide slopes in SW Dorset. Quart J Eng Geol 5:205–222
Brunsden D, Doornkamp JC, Fookes PG, Jones DKC, Kelly JMH (1975) Large-scale geotechnical mapping and highway engineering design. Quart J Eng Geol 8:227–253
Brunsden D, Jones DKC, Martin RP, Doornkamp JC (1981) The geomorphological character of part of the low Himalaya of Eastern Nepal. Z Geomorphol Suppl Bd 37:25–72
Caine N, Mool PK (1982) Landslides in the Kolpu Khola drainage, Middle Mountains, Nepal. Mt Res Dev 2:157–173
Carrara A, Meranda L (1976) Landslide inventory in Northern Calabria, Southern Italy. Bull Geol Soc Am 87:1153–1162
Central Bureau of Statistics (CBS) (2002) Population of Nepal: Village development committee/municipalities, population census 2001-selected tables. National Planning Commission Secretariat. His Majesty’s Government, Nepal, Kathmandu
Chapin FS, Matson PA, Mooney HA (2002) Principles of terrestrial ecosystem ecology. Springer, New York
Cruden DM (1988) Thresholds for catastrophic instabilities in sedimentary rock slopes, some examples from the Canadian Rockies. Z Geomorphol Suppl Bd 67:67–76
Cruden DM (1991) A simple definition of a landslide. Bull Int As Geol 43:27–29
Cruden DM, Varnes DJ (1996) Landslide types and processes. Chapter 3 In: Turner AK, Schuster RL (eds) landslides investigation and mitigation. Special Report 247, National Research Council, Transportation Research Board, National Academy of Sciences, Washington DC pp 36–75
Dahal RK, Hasegawa S, Nonomura A, Yamanaka M, Dhakal S, Paudyal P (2008) Predictive modelling of rainfall-induced landslide hazard in the Lesser Himalaya of Nepal based on weights-of-evidence. Geomorphol 102(3–4):496–510
Dai FC, Lee CF, Li J, Xu ZW (2001) Assessment of landslide susceptibility on the natural terrain of Lantau Island, Hong Kong. Environ Geol 40:381–391
Deoja B, Dhital MR, Thapa B, Wagner A (1991) Mountain risk engineering handbook. International Center for Integrated Mountain Development (ICIMOD), Kathmandu
Dhital MR, Upreti BN, Dangol V, Bhandari AN, Bhattarai TN (1991) Geological engineering methods applied in mountain road survey: an example from Baitadi-Darchula Road Project (Nepal). J Nepal Geol Soc 7:49–67
Dhital MR, Khanal N, Thapa KB (1993) The role of extreme weather events, mass movements, and land use changes in increasing natural hazards, a report of the preliminary field assessment and workshop on causes of recent damage incurred in south-central Nepal, July 19–20 1993. ICIMOD, Kathmandu
Dietrich WE, Dunne T (1978) Sediment budget for a small catchment in mountainous terrain. Z Geomorphol Suppl Bd 29:191–206
Dietrich WE, Reiss R, Hsu ML, Montgomery DR (1995) A process-based model for colluvial soil depth and shallow landsliding using digital elevation data. Hydrol Process 9:383–400
DMG (Department of Mines and Geology) (2007) Geological maps of Exploration Block-1, Dhangadi, far western Nepal; Block 4; Lumbini, mid western Nepal; and Block 5, western central Nepal. Petroleum Promotion Exploration Project, Department of Mines and Geology, Government of Nepal, Kathmandu
Gerrard AJ, Gardner RAM (2000) The role of landsliding in shaping the landscape of the middle hills, Nepal. Z Geomorphol Suppl Bd 122:47–62
Ghimire SK, Higaki D, Bhattarai TP (2006) Gully erosion in the Siwalik Hills, Nepal: estimation of sediment production from active ephemeral gullies. Earth Surf Process Landf 31(2):155–165
Greenway DR (1987) Vegetation and slope stability. In: Anderson MG, Richards KS (eds) Slope stability. Wiley, New York, pp 187–230
Gritzner ML, Marcus WA, Aspinall R, Custer SG (2001) Assessing landslide potential using GIS, soil wetness modelling and topographic attributes, Payette River, Idaho. Geomophol 37:149–165
Guzzetti F, Carrara A, Cardinali M, Reichenbach P (1999) Landslide hazard evaluation: a review of current techniques and their application, in a multi-scale study, central Italy. Geomorphol 31:181–216
Guzzetti F, Ardizzone F, Cardinali M, Galli M, Reichenbach P (2008) Distribution of landslides in the Upper Tiber River basin, central Italy. Geomorphol 96(1):105–122
Hasegawa S, Dahal RK, Yamanaka M, Bhandary NP, Yatabe R, Inagaki H (2008) Causes of large scale landslides in the Lesser Himalaya of Central Nepal. Environ Geol 57(6):1423–1434
Heuberger H, Masch L, Preuss E, Schrocker A (1984) Quaternary landslides and rock fusion in central Nepal and in the Tyrolean Alps. Mt Res Dev 4:345–362
Hudson JA, Harrison JP (1997) Engineering rock mechanics—an introduction to the principles. Pergamon Press, Elsevier Science, Oxford
Ives JD, Messerli B (1981) Mountain hazards mapping in Nepal; introduction to an applied mountain research project. Mt Res Dev 1:223–230
Kienholz H, Hafner H, Schneider G, Tamrakar R (1983) Mountain hazards mapping in Nepal’s Middle Mountains, maps of land use and geomorphic damages (Kathmandu-Kakani area). Mt Res Dev 3(3):195–220
Laban P (1979) Landslide occurrence in Nepal. His Majesty’s Government (HMG Nepal/Food and Agriculture Organisation (FAO) and United Nation Development Program (UNDP), Ministry of Forest, Department of Soil Conservation, Integrated Watershed Management, Kathmandu
Lavé J, Avouac JP (2000) Active folding of fluvial terraces across the Siwaliks Hills (Himalayas of central Nepal). J Geophys Res 105:5735–5770
Lavé J, Avouac JP (2001) Fluvial incision and tectonic uplift across the Himalayas of central Nepal. J Geophys Res 106(Bll):26561–26591
Lee S, Choi J, Min K (2002) Landslide susceptibility analysis and verification using a Bayesian probability model. Environ Geol 43:120–131
Marston RA, Miller MM, Devkota LP (1998) Geoecology and mass movements in the Manaslu Ganesh and Langtang-Jural Himals, Nepal. Geomorphol 26:139–150
Mather AE, Griffiths JS, Stokes M (2003) Anatomy of a ‘fossil’ landslide from the Pleistocene of SE Spain. Geomorphol 50:135–149
Meentemeyer RK, Moody A (2000) Automated mapping of alignment between topography and geologic bedding planes. Comput Geosci 26(7):815–829
Molnar P (1990) A review of the seismicity and the rate of active underthrusting and deformation at the Himalaya. J Himal Geol 1:131–154
Montgomery DR, Dietrich WE (1994) A physically based model for the topographic control of shallow landsliding. Water Resour Res 30(4):1153–1171
Nakata T (1989) Active faults of the Himalaya of India and Nepal. Geol Soc Am Special Paper 232:243–264
Pachauri AK, Pant M (1992) Landslide hazard mapping based on geological attributes. Eng Geol 32:81–100
Pack RT, Tarboton DG, Goodwin CN, Prasad A (2005) SINMAP 2, a stability index approach to terrain stability hazard mapping. Technical Description and User’s Manual for version 2.0. Utah State University, USA
Paulin GL, Bursik M (2009) Logisnet: a tool for multi method, multiple soil layers slope stability analysis. Comput Geosci 35(5):1007–1016
Rautela P, Lakhera RC (2000) Landslide risk analysis between Giri and Tons Rivers in Himachal Himalaya (India). Int J Appl Earth Obs Geoinfo 2(3–4):153–160
Roering JJ, Kirchner JW, Dietrich WE (2005) Characterizing structural and lithologic controls on deep-seated landsliding: Implications for topographic relief and landscape evolution in the Oregon Coast Range, USA. Geol Soc Am Bull 117:654–668
Selby MJ (1988) Landforms and denudation of the high Himalaya of Nepal: results of continental collision. Z Geomorphol Suppl Bd 69:133–152
Selby MJ (1993) Hillslope materials and processes, 2nd edn. Oxford University Press, Oxford
Tamrakar NK, Yokota S, Osaka O (2002) A toppled structure with sliding in the Siwalik Hills, midwestern. Nepal Eng Geol 64:339–350
Tarboton DG (1997) A new method for the determination of flow directions and contributing areas in grid digital elevation models. Water Resour Res 33(2):309–319
Tokuoka T, Takayasu K, Yoshida M, Hisatomi K (1986) The Churia(Siwalik) group of Arung Khola area, west Central Nepal. Memoirs Faculty Sci Shimane Univ 20:135–210
Valdiya KS (1992) The main boundary thrust zone of the Himalaya. India Ann Tectonicae 6 (suppl): 54–84
Van Westen CJ (1997) Statistical landslide hazard analysis. ILWIS Application Guide, ITC, Netherlands, pp 73–84
Van Westen CJ, Van Asch TWJ, Soeters R (2006) Landslide hazard and risk zonation–why is it still so difficult? Bull Eng Geol Env 65:167–184
Varnes DJ (1978) Slope movement types and processes. In: Schuster RL, Krizek RJ (eds) Landslide: analysis and control. Special Report 176. Transportation research board. National Academy of Science, Washington, pp 11–33
Wagner A (1981) Rock structure and slope stability study of Waling area, central west Nepal. J Nepal Geol Soc 1(2):37–43
Wagner A (1983) The principal geological factors leading to landslides in the foothills of Nepal: a statistical study of 100 landslides—steps for mapping the risk of landslides. HELVETAS—Swiss Technical Cooperation and ITECO–Company for International Cooperation and Development, unpubl report
Waters RS (1958) Morphological mapping. Geography 43:10–17
Yagi H, Oi H (1993) Hazard mapping on large-scale landslides in the Lower Nepal Himalayas, Final Proceedings 7th International Conference and Field Workshop on Landslides. Czech and Slovak Republics, 28 August to 15 September
Zimmermann M, Bichsel M, Kienholz H (1986) Mountain Hazard Mapping in Khumbu Himalayas, Nepal. Mt Res Dev 6(1):29–40
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I am thankful to the Graduate School of Environmental Science (GSES), Hokkaido University, Japan for providing me an opportunity and facilities to prepare this paper. My special thanks go to Dr. Teiji Watanabe, Division of Earth System Science, GSES for his valuable suggestions and feedbacks in preparing this paper. I would like to extend my thanks to the editor and the reviewers, whose suggestions and comments helped to improve my manuscript.
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Ghimire, M. Landslide occurrence and its relation with terrain factors in the Siwalik Hills, Nepal: case study of susceptibility assessment in three basins. Nat Hazards 56, 299–320 (2011). https://doi.org/10.1007/s11069-010-9569-7
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DOI: https://doi.org/10.1007/s11069-010-9569-7