Abstract
It was thought for a long time that only the younger and tectonically active mountains are prone to landslides and hence more attention was given in studying them the world over. But, when the landslides have started occurring in other mountain regions of high rainfall and human interventions also, these mountains too came under the purview of landslide studies. The studies thus widened to the other mountains revealed that the various geological/terrain parameters and the degree of anthropogenic activities occur in different combinations and assign varying grades of landslide probabilities. According to it, these mountains succumb to different degrees of landslides when heavy rainfall occurs. The state of Kerala, which is 600 km long in North Northwest–South Southeast and 35 to 120 km broad in East-West directions, is one such a region of recurring landslides. It is a unique physiographic/geomorphic province with highly elevated NNW-SSE oriented Western Ghat Mountains in the east, that are rimmed by the sub parallel systems of landforms like composite slopes, marginally raised lateritic uplands and the coastal plains successively in the west with gradual descending elevation, thus providing a step like topography. The regular annual rainfall of the southwest monsoons cause devastating landslides in Kerala due to the unique geomorphic setting. So the present study was carried out to analyse the geomorphology of the region in details, which is dominantly evolved by the tectonics, to elucidate its input over the landslides. In the study, the geomorphic features were studied in detail using the (i) satellite false colour composite imagery wrapped over the digital elevation model of the terrain, (ii) shaded relief maps and (iii) the topographic cross sections drawn over the above satellite data wrapped 3D terrain model. These were accomplished using the advanced options available with geospatial technology. The study revealed that due to the high degree of deformation and the resultant development of geomorphology of the study area, the rainwater infiltrates and cause landslides in the form of rock and cliff topples, rock and cliff falls, landslides, talus and debris falls/flows.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
A** RS, Vinod PG, Menon ARR (2014) Landslide hazard zonation using RS and GIS techniques: a case study of Meenachil and Kanjirappally Taluk, Kottayam District, Kerala, India. Proceedings of 26th Kerala Science Congress Pookode, Wayanad: 28-31 Jan. 2014. 1797 - 1803
Anbazhagan S, Sa**kumar KS (2011) Geoinformatics in terrain analysis and landslide vulnerability map** in parts of Western Ghats, India, Geoinformatics in Applied Geomorphology. CRC Press, pp 291–315
Anderson EM (1951) The dynamics of faulting and dyke formation with application to Britain. Oliver and Boyd, Edinburgh, p 206
Arun Kumar A, Kapoor U, Dhar S, Chingkhei RK (2008) Landslide Hazard Zonation Atlas of Northeast India. Indian Landslides 1(2):11–18
Bacchini M, Zannoni A (2003) Relations between rainfall and triggering of debris-flow: case study of Cancia (Dolomites, Northeastern Italy). Nat Hazards Earth Syst Sci 3:71–79
Bali R, Bhattacharya AR, Singh TN (2009) Active tectonics in the Outer Himalaya: dating a landslide event in the Kumaun sector. Earth Sci India 2(IV):276–288 ISSN: 0974 – 8350
Bansode RB, Pradhan SK (1975) Landslides in Nepal Himalaya and their influence on the Kosi dam. Proceedings, Seminar on Landslides and Toe Erosion problems with special reference to Himalayan region, Gangtok, 247
Brabb EE (1984) Innovative approaches to landslide hazard map**. In: Proc. 4th Int.Symp. Landslides, Toronto. 1. pp. 307–324
Cardinali M, Galli M, Guzzetti F, Ardizzone F, Reichenbach P, Bartoccini P (2006) Rainfall induced landslides in December 2004 in south-western Umbria, central Italy: types, extent, damage and risk assessment. Nat Hazards Earth Syst Sci 6:237–260
Champati Ray PK, Parvaiz I, Lakhera RC (2008) Seismically triggered landslides and associated hazard assessment in Kashmir Himalaya. Indian Landslides 1:1–10
Chen XL, Zhou Q, Ran H, Dong R (2012) Earthquake-triggered landslides in southwest China. Nat Hazards Earth Syst Sci 12(351–363):2012. https://doi.org/10.5194/nhess-12-351
Christaras B (1994) Slope stability investigations in relation to the neotectonic conditions along the South Western coast of Athos Peninsula (N.Greece) - the case of Simonos Petra Monestry. Proceedings of 7th International IAEG Congress, Rotterdam, 1577-1583
Dai FC, Lee CF, Wang S (1999) Analysis of rainstorm-induced slide debris flows on natural terrain of Lantau Island, Hong Kong. Eng Geol 51(4):279–290
Dai FC, Lee CF, Wang S (2003) Characterization of rainfall-induced landslides. Int J Remote Sens 24(23):4817–4834. https://doi.org/10.1080/014311601131000082424
Dave VKS, Joshi BC (1988) Landslide hazard zones in the Nayar basin, Garhwal Himalaya, Proceedings, Sixth Indian Geological Congress, Rurkee, India, February 21–24: 137-145
De Costa Nunes AJ (1969) Landslides in soils of decomposed rocks due to intense rainstorms, Internat. Conf. Soil Mechanics and Foundation Engineering, 7th, Mexico City 1969, Proc, Vol (2): 547-554
Densmore AL, Michael A, Ellis Robert S, Anderson (1998) Landsliding and the evolution of normal-fault-bounded mountain. J Geophys Res 103(b7):15,203–15,219
Didwal RS (1980) Occurrence of landslides in Jammu Province of J and K state and their control, Proceedings, International Symposium on Landslides, (ISL 1980), April 7-11, New Delhi, Vol (1): 37-40
Emmanuel J, Gabeta D, Burbank W, Jaakko K, Putkonen B, Pratt-Sitaula A, Ojha T (2004) Rainfall thresholds for landsliding in the Himalayas of Nepal. Geomorphology 63:131–143
Forrester DG (1980) Two landslides on New South Wales Highways, Proceedings, International Symposium on Landslides, (ISL 1980), April 7-11, New Delhi, Vol (1): 113-144
Galeandro A, Simon V (2012) Infiltration processes in fractured and swelling soils and their influence on the stability of surficial covers. Rend Online Soc Geol Ital 2(1):518–520
Galeandro A, Simunek J, Simon V (2011) Analysis of infiltration processes into fractured and swelling soils as triggering factors of landslides. In: Proceedings of the Second World Landslide Forum. Roma, 3–7
Ganesha Raj K, Paul MA, Hegde VS, Nijagunappa R (2001) Lineaments and seismicity of Kerala a remote sensing based analysis. J Indian Soc Remote Sens 29(4):203–211
Ghobadi MH (1994) Geology and slope stability in the northern Illawara, NSW, Australia. Proceedings. 7th IAEG Conference, Lisboa, Portugal, Vol (3):1307-1314
Gill JC, Bruce D, Malamud (2017) Anthropogenic processes, natural hazards, and interactions in a multi-hazard framework. Earth-Sci Rev 166:246–269
Glade T (2003) Landslide occurrence as a response to land use change: a review of evidence from New Zealand. CATENA 51:297–314
Gogte BS (1986) Landslip vulnerability of some Indian rocks; a factor related to their petrological and physical nature. Proceedings. Seminar on Engineering Geophysics, Prospectives and Prospects; Hyderabad, India: 62–68
Gujarathi P, Mane SJ (2013) Landslides zones of nearby areas of MalinVillage, Pune District, Maharashtra using GIS techniques. Int J Sci Res (IJSR) ISSN (Online) 2319-7064:443–448
Guzzetti F (2006) Landslide hazard and risk assessment. Mathematisch Naturwissenschaftlichen Fakultät der Rheinischen Friedrich-Wilhelms-Universität, University of Bonn, Bonn, Germany Ph.D. Thesis. 389 pp. https://geomorphology.irpi.cnr.it/Members/fausto/PhD-dissertation. Accessed Jun 2006
Guzzetti F, Reichenbach P, Cardinali M, Galli M, Ardizzone F (2005) Probabilistic landslide hazard assessment at the basin scale. Geomorphology 72:272–299. https://doi.org/10.1016/j.geomorph.2005.06.002
Guzzetti F, Peruccacci S, Rossi M, Stark CP (2008) The rainfall intensity-duration control of shallow landslides and debris flows: an update. Landslides 5(1):3–17
Guzzetti F, Mondini AC, Cardinali M, Fiorucci F, Santangelo M, Chang KT (2012) Landslide inventory maps: New tools for an old problem. Earth-Sci Rev 112(1–2):42–66
Hungr O, Leroueil S, Picarelli L (2013) The Varnes classification of landslide types, an update. Landslides 11(2):167–194. https://doi.org/10.1007/s10346-013-0436-y
Janardhana MR, Vinutha DN, Ahamed A-A, Al-Qadhi AD (2016) Landslides in Coorg District of Karnataka state. Int J Innov Res Sci Eng Technol 5(6):10120–10125. https://doi.org/10.15680/IJIRSET.2015.0506112
John A (1964) Slope morphological features resulting from gravitation. Z Geomorphic SB 5:59–72
Kahlon S, Vishwa BS, Chandel, Brar KK (2014) Landslides in Himalayan Mountains: a Study of Himachal Pradesh, India. Int J IT Eng Appl Sci Res 3(9):28–34
Korup O, Densmore AL, Schlunneger F (2010) The role of landslides in mountain range evolution. Geomorphology 120:77–90
Kuriakose S, Lillisand, Sankar GE, Muraleedharan C (2009) History of landslide vulnerability and a chorology of landslide—prone areas in the Western Ghats of Kerala, India. Environ Geol 57:1553–1568
Lillesand TM (1989) Remote sensing and image Interpretation. Wiley, p 721
Luzi L, Pergalani F, Terlien MTJ (2000) Slope vulnerability to earthquakes at sub regional scale using probabilistic techniques and geographic information systems. Eng Geol 58:313–336
Mehrotra GS, Sarkar S, Kanungo DP (1994) A geological appraisal of landslide hazards in East Sikkim Himalaya. J Himal Geol 1:35–43
Meusburger K, Alewell C (2008) Impacts of anthropogenic and environmental factors on the occurrence of shallow landslides in an alpine catchment (Urseren Valley, Switzerland). Nat Hazards Earth Syst Sci 8:509–520
Moeyersonsa J, Trefois J, Lavreau D, Alimasi I, Badriyo B, Mitima M, Mundala DO, Munganga L, Nahimana (2004) A geomorphological assessment of landslide origin at Bukavu, Democratic Republic of the Congo. Eng Geol 72:73–87
Nair MM (1987) Coastal geomorphology of Kerala, India. J Geol Soc India 29:450–458
Ojha T, DeCelles PG, Chaudhary S, Srivastava P (2013) Relationships among landslides, major geological structures, seismic epicenters, and fluvial knick zones, in far West Nepal Himalayas: a GIS and optically stimulated luminescence (OSL) approach. Int J Landsl Environ 1(1):69–70
Pachauri AK, Pant M (1992) Landslide hazard map** based on geological attributes. Eng Geol 32:81–100
Pardeshi SD, Pardeshi SS, Nagare V (2009) A study of effect of landslide on human environment in Thana district, Maharashtra state. Deccan Geogr 47(1):45–56
Prakash P, Parthasaradhi EVR (1988) Monitoring landslides in Dihang and Subansiri river basin, Arunachal Pradesh. J Geol Soc India 31:449–454
Rajendran CP, Biju John K, Sreekumari, Rajendran K (2009) Reassessing the earthquake hazard in Kerala based on the historical and current seismicity. J Geol Soc India 73:785–802
Ramasamy SM (2003) Landslides and Quaternary tectonics of South India. Spec. Vol. on South Asian Geological Congress. 192-200
Ramasamy SM (2006) Remote sensing and active tectonics of South India. Int J Remote Sens, Taylor and Francis, London 27(20):4397–4431
Ramasamy SM, Muthukumar M (2008) Geospatial modelling of geosystems and landslides map** and mitigation, the Nilgiri Mountains, South India. Indian. Landslides 1(1):45–54
Ramasamy SM, Suresh F, Neelakantan R (1996) Frequent landslides in Nilgiris, India - A phenomenon related to Pleistocene Tectonism. Proceedings of the seventh International Symposium on Landslides, Trondheim, Norway, 345 – 349
Ramasamy SM, Balaji S, Kumanan CJ (1999) Tectonic evolution of Early Precambrian South Indian Shield (Rocks) using remotely sensed data. Photonirvachak J Indian Soc Remote Sens Dehradun 27(2):91–104
Ramasamy SM, Neelakantan R, Suresh F (2006) Predictive and preventive modelling for landslides in the Nilgiris, South India—using remote sensing and GIS. In: Landslides: a perception and initiatives of DST, Chapter-16. Indian Society of Engineering Geology, pp 177–203
Ramasamy SM, Kumanan CJ, Neelakantan R, Muthukumar M (2008) GIS based slope analysis for landslide hazard zonation map**. Nilgiri Mountains. South India. Int J Geoinform 4:47–57
Ramasamy SM, Muthukumar M, Subagunasekar M (2014) Drainage and anthropogenic aberrations in Himalayan landslides, Uttrakhand, India. Indian Landslides 7(1 & 2):9–22
Ramasamy SM, Muthukumar M, Subagunasekar M (2015) Malin-Maharashtra landslides: a disaster triggered by tectonics and anthropogenic phenomena. Curr Sci 108(8):1428–1430
Ramasamy SM, Gunasekaran S, Rajagopal N, Saravanavel J, Kumanan CJ (2019) Flood (2018) and the Status of Reservoir Induced Seismicity in Kerala, India. J Nat Hazards
Rodriguez CE, Bommer JJ, Chandler RJ (1999) Earthquake-induced landslides: 1980–1997. Soil Dyn Earthq Eng 18(5):325–346
Romkens MJM, Prasad SN (2006) Rain Infiltration into swelling/shrinking/cracking soils. Agr Water Manage – V 86:196–205
Sa**kumar KS, Rani VR (2015) Contrasting anthropogenically influenced landslides in two different terrain conditions in the southwestern part of Peninsular India. In: Lollino G. et al., (Eds.), Engineering Geology for Society and Territory, Vol (2):1005–1010
Seshagiri DN, Badrinarayanan S, Upendran R, Lakshminathan CB, Sirnivasan V (1982) The Nilgiris Landslides. Geol Surv India Misc Publ 57:41
Sharifi R, Solgi A, Pourkermani M (2013) A study of the relationship between landslide and active tectonic zones: a case study in Karaj Watershed management. Open J Geol 3(3):34335, 7 pages. https://doi.org/10.4236/ojg.2013.33027
Singh HN, Raghavan V (1989) A note on earth tremor of September 2, 1988 in Trivandrum district, Kerala. J Geol Soc India 36:323–325
Skilodimou HD, Bathrellos GD, Koskeridou E, Soukis K, Rozos D (2018) Physical and anthropogenic factors related to landslide activity in the Northern Peloponnese, Greece. Land 7:85. https://doi.org/10.3390/land7030085:1-18
Soman K (2002) Geology of Kerala. Geological Society of India, Banglore 376p
The Hindu (2020) https://www.thehindu.com/news/national/kerala-floods-declared-calamity-of-severe-nature/article24738072.ece. Acessed 6 Sept 2020
Todd DK (1980) Groundwater Hydrology, 2nd edn. Wiley, New York, p 535
Varnes DJ (1978) Slope movements: types and processes. In: Schuster RL, Krizek RJ (eds) Landslide Analysis and Control, National Academy of Sciences, Special Report 176. Transportation Research Board, Washington D.C., pp 11–33
Vijith H, Madhu G (2008) Estimating potential landslide sites of an upland sub-watershed in Western Ghats of Kerala (India) through frequency ratio and GIS. Environ Geol 55(7):1397–1405. https://doi.org/10.1007/s00254-007-1090-2
Wasowski J (1998) Understanding rainfall-landslide relationships in man modified environments: a case history from CaramanicoTerme, Italy. Environ Geol 35(2):197–209
Xu XW, Zhang PZ, Wen XZ (2005) Features of active tectonics and recurrence behaviours of strong earthquakes in the western Sichuan province and its adjacent regions. Seismol Geol 27:446–461
Yang C-M, Chen J-C, Peng L-L, Yang J-S, Chou C-H (2002) Chi-Chi Earthquake-caused Landslide: grey prediction model for pioneer vegetation recovery monitored by satellite images. Bot Bull Acad Sim 43:69–75
Acknowledgements
The authors acknowledge Bharathidasan University (Tiruchirappalli), Alagappa University (Karaikudi) and Gandhigram Rural Institute—Deemed University (Dindigul) for having extended facilities for the authors for present study.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Ramasamy, S., Gunasekaran, S., Saravanavel, J. et al. Geomorphology and Landslide Proneness of Kerala, India A Geospatial study. Landslides 18, 1245–1258 (2021). https://doi.org/10.1007/s10346-020-01562-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10346-020-01562-9