Journal of Forest and Environmental Science

Institute of Forest Science, kangwon National University (강원대학교 산림과학연구소)
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Influences of Forest Fire on Forest Floor and Litterfall in Bhoramdeo Wildlife Sanctuary (C.G.), India

  • Received : 2017.03.25
  • Accepted : 2017.05.08
  • Published : 2017.11.30
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Abstract

Tropical forests play a key role for functioning of the planet and maintenance of life. These forests support more than half of the world's species, serve as regulators of global and regional climate, act as carbon sinks and provide valuable ecosystem services. Forest floor biomass and litterfall dynamics was measured in different sites influenced by fire in a seasonally dry tropical forest of Bhoramdeo wildlife sanctuary of Chhattisgarh, India. The forest floor biomass was collected randomly placed quadrats while the litterfall measured by placing stone-block lined denuded quadrat technique. The seasonal mean total forest floor biomass across the fire regimes varied from $2.00-3.65t\;ha^{-1}$. The total litterfall of the study sites varied from $4.75-7.56t\;ha^{-1}\;yr^{-1}$. Annual turnover of litter varied from 70-74% and the turnover time between 1.35-1.43 years. Monthly pattern of forest floor biomass indicated that partially decayed litter, wood litter and total forest floor were differed significantly. The seasonal variation showed that leaf fall differed significantly in winter season only among the fire regimes while the wood litter was found non significant in all the season. This study shows that significant variation among the site due to the forest fire. Decomposition is one of the ecological processes critical to the functioning of forest ecosystems. The decomposing wood serves as a saving account of nutrients and organic materials in the forest floor. Across the site, high fire zone was facing much of the deleterious effects on forest floor biomass and litter production. Control on such type of wildfire and anthropogenic ignition could allow the natural recovery processes to enhance biological diversity. Chronic disturbances do not provide time for ecosystem recovery; it needs to be reduced for ecosystem health and maintaining of the high floral and faunal biodiversity.

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References

  1. Aquiar ACF, Bicudo SJ, Sobrinho JRSC, Martins ALS, Coelho KP, de Moura EG. 2010. Nutrient recycling and physical indicators of an alley cropping system in a sandy loam soil in the pre- Amazon region of Brazil. Nutrient Cycling in Agroecosystems 86: 189-198. https://doi.org/10.1007/s10705-009-9283-6
  2. Arunachalam A, Arunachalam K, Pandey HN, Tripathi RS. 1998. Fine litter-fall and nutrient dynamics during forest regrowth in the humid subtropics of north-eastern India. For Ecol Manage 110: 209-219. https://doi.org/10.1016/S0378-1127(98)00282-5
  3. Averti I, Dominique N. 2011. Litterfall, Accumulation and Decomposition in Forest Groves Established on Savannah in the Plateau Teke, Central Africa. J Environ Sci Technol 4: 601-610. https://doi.org/10.3923/jest.2011.601.610
  4. Bargali SS. 1994. Forest floor development in Eucalyptus tereticornis Sm. plantations in a part of Central Himalayan tarai belt. Range Management and Agroforestry 15: 61-68.
  5. Bargali SS. 1995. Litter fall, nutirent return and leaf decomposition in an age series of eucalypt plantations in central Himalaya. Oecologia Montana 4: 31-38.
  6. Bernhard-Reversat F. 1972. Decomposition De La Litiere De Feuilles En Foret Ombrophile De Basse Cote-D'Ivoire. Oecol Plant 7: 279-300.
  7. Biswas S, Khan DK. 2011. Major nutrient dynamics of two plant species at matha protected forest of Purulia, West Bengal, India. Int J Environ Sci 2: 210-219.
  8. Boerner REJ. 1984. Foliar Nutrient Dynamics and Nutrient Use Efficiency of Four Deciduous Tree Species in Relation to Site Fertility. J Appl Ecol 21: 1029-1040. https://doi.org/10.2307/2405065
  9. Bray JR, Gorham E. 1964. Litter Production in Forests of the World. Ad Ecol Res 2: 101-157.
  10. Brown S, Lugo AE. 1982. The Storage and Production of Organic Matter in Tropical Forests and Their Role in the Global Carbon Cycle. Biotropica 14: 161-187. https://doi.org/10.2307/2388024
  11. Burghouts TBA, Van Straalen NM, Bruijnzeel LA. 1998. Spatial Heterogeneity of Element and Litter Turnover in a Bornean Rain Forest. J Trop Ecol 14: 477-506. https://doi.org/10.1017/S0266467498000352
  12. Champion HG, Seth SK. 1968. A Revised Survey of the Forest Types of India. Government of India Publication, New Delhi.
  13. Chaturvedi OP, Singh JS. 1987. A quantitative study of the forest floor biomass, litterfall and nutrient return in Pinus roxburghii forest in Kumaun Himalaya. Vegetatio 71: 97-106.
  14. Clark DA, Brown S, Kicklighter DW, Chamber JQ, Thomlinson JR, Ni J, Holland EA. 2001. Net Primary Production in Tropical Forests: An Evaluation and Synthesis of Existing Field Data. Ecological Applications 11: 371-384. https://doi.org/10.1890/1051-0761(2001)011[0371:NPPITF]2.0.CO;2
  15. Dawoe EK, Isaac ME, Quashie-Sam J. 2010. Litterfall and litter nutrient dynamics under cocoa ecosystems in lowland humid Ghana. Plant Soil 330: 55-64. https://doi.org/10.1007/s11104-009-0173-0
  16. Dezzeo N, Chacon N, Sanoja E, Picon G. 2004. Changes in soil properties and vegetation characteristics along a forest-savanna gradient in southern Venezuela. For Ecol Manage 200: 183-193. https://doi.org/10.1016/j.foreco.2004.06.016
  17. Glumphabutr P, Kaitpraneet S. 2007. Aboveground Biomass and Litterfall of Natural Evergreen Forest in Eastern Region of Thailand. Thai J For 26: 70-81.
  18. Golley FB, McGinnis JT, Clements RG, Child GI, Duever MJ. 1975. Mineral Cycling in a Tropical Moist Forest Ecosystem. University of Georgia Press, Athens, USA, 248 pp.
  19. Gray JT, Schlesinger WH. 1981. Nutrient cycling in Mediterranean Type Ecosystems. In: Resource Use by Chaparral and Matorral. A Comparison of Vegetation Function in Two Mediterranean Type Ecosystems (Miller PC, ed). Ecological Studies, SpringerVerlag, New York, pp 259-286.
  20. Isichei AO, Ekeleme F, Jimoh BA. 1986. Changes in a secondary forest in southwestern Nigeria following a ground fire. J Trop Ecol 2: 249-256. https://doi.org/10.1017/S0266467400000870
  21. Jenny H, Gessel SP, Bingham FT. 1949. Comparative study of decomposition rates of organic matter in temperate and tropical regions. Soil Sci 68: 419-432. https://doi.org/10.1097/00010694-194912000-00001
  22. Jhariya MK. 2010. Analysis of vegetational structure, diversity and fuel load in fire affected areas of tropical dry deciduous forests in Chhattisgarh. M.Sc. thesis. I.G.K.V., Raipur (C.G.), pp 86.
  23. Jhariya MK. 2014. Effect of forest fire on microbial biomass, storage and sequestration of carbon in a tropical deciduous forest of Chhattisgarh. Ph.D. thesis. I.G.K.V., Raipur (C.G.), pp 259.
  24. Jhariya MK, Yadav DK. 2016. Understory vegetation in natural and plantation forest ecosystem of Sarguja (C.G.), India. J Appl Nat Sci 8: 668-673.
  25. Jhariya MK, Bargali SS, Swamy SL, Kittur B. 2012. Vegetational Structure, Diversity and Fuel Load in Fire Affected Areas of Tropical Dry Deciduous Forests in Chhattisgarh. Vegetos 25: 210-224.
  26. Jhariya MK, Bargali SS, Swamy SL, Kittur B, Bargali K, Pawar GV. 2014. Impact of Forest Fire on Biomass and Carbon Storage Pattern of Tropical Deciduous Forests in Bhoramdeo Wildlife Sanctuary, Chhattisgarh. Int J Ecol Environ Sci 40: 57-74.
  27. Johansson MB. 1995. The chemical composition of needle and leaf litter from Scots pine, Norway spruce and white birch in Scandinavian forests. Forestry 68: 49-62. https://doi.org/10.1093/forestry/68.1.49
  28. Jordan CF. 1985. Nutrient cycling in tropical forest ecosystems. Wiley, Chichester, UK, pp 190.
  29. Khiewtam RS, Ramakrishnan PS. 1993. Litter and fine root dynamics of relic sacred grove forest at Cherrapunji in northeastern India. For Ecol Manage 60: 327-344. https://doi.org/10.1016/0378-1127(93)90087-4
  30. Kinnard M, O'Brien T. 1998. Letter from Indonesia: Forest Fires that Ranged throughout Indonesia are Linked to a Quick El Nino. Wildife Conservation, March/April 1998.
  31. Kittur B, Jhariya MK, Lal C. 2014b. Is the forest fire can affect the regeneration and species diversity. Ecol Environ Conserv 20: 989-994.
  32. Kittur BH, Swamy SL, Bargali SS, Jhariya MK. 2014a. Wildland Fires and Moist Deciduous Forests of Chhattisgarh, India: Divergent Component Assessment. J Forestry Res 25: 857-866. https://doi.org/10.1007/s11676-014-0471-0
  33. Kumar A, Jhariya MK, Yadav DK. 2016. Vegetation Dynamics in Plantation Sites of Collieries. Nature, Environment and Pollution Technology 15: 1285-1291.
  34. Kumar BM, Deepu JK. 1992. Litter production and decomposition dynamics in moist deciduous forests of the Western Ghats in Peninsular India. For Ecol Manage 50: 181-201. https://doi.org/10.1016/0378-1127(92)90335-7
  35. Kumar JIN, Sajish PR, Kumar RN, Patel K. 2011. Biomass and Net Primary Productivity in Three Different Aged Butea Forest Ecosystems in Western India, Rajasthan. Iranica J Energy Environ 2: 01-07.
  36. Lebret M, Nys C, Forgeard F. 2001. Litter production in an Atlantic beech (Fagus sylvatica L.) time sequence. Ann For Sci 58: 755-768. https://doi.org/10.1051/forest:2001161
  37. Liu L, Gundersen P, Zhang T, Mo J. 2012. Effects of phosphorus addition on soil microbial biomass and community composition in three forest types in tropical China. Soil Biology Biochemistry 44: 31-38. https://doi.org/10.1016/j.soilbio.2011.08.017
  38. Lugo AE, Gonzalez-Liboy JA, Cintron B, Dugger K. 1978. Structure, Productivity, and Transpiration of a Subtropical Dry Forest in Puerto Rico. Biotropica 10: 278-291. https://doi.org/10.2307/2387680
  39. Meentemeyer V, Box EO, Thompson R. 1982. World Patterns and Amounts of Terrestrial Plant Litter Production. BioScience 32: 125-128. https://doi.org/10.2307/1308565
  40. Minderman G. 1968. Addition, Decomposition and Accumulation of Organic Matter in Forests. J Ecol 56: 355-362. https://doi.org/10.2307/2258238
  41. Murphy PG, Lugo AE. 1986. Ecology of Tropical Dry Forests. Ann Rev Ecol Syst 17: 67-88. https://doi.org/10.1146/annurev.es.17.110186.000435
  42. Odiwe AI, Muoghalu JI. 2003. Litterfall dynamics and forest floor litter as influenced by fire in a secondary lowland rain forest in Nigeria. Tropical Ecology 44: 243-251.
  43. Olson JS. 1963. Energy Storage and the Balance of Producers and Decomposers in Ecological Systems. Ecology 44: 322-331. https://doi.org/10.2307/1932179
  44. Ostertag R, Scatena FN, Silver WL. 2003. Forest Floor Decomposition Following Hurricane Litter Inputs in Several Puerto Rican Forests. Ecosystems 6: 261-273. https://doi.org/10.1007/PL00021512
  45. Pandey RR, Sharma G, Tripathi SK, Singh AK. 2007. Litterfall, litter decomposition and nutrient dynamics in a subtropical natural oak forest and managed plantation in northeastern India. For Ecol Manage 240: 96-104. https://doi.org/10.1016/j.foreco.2006.12.013
  46. Parthasarathy N. 1992. Vegetation, root biology and nutrient cycling. In: Ecological Studies in Agasthyamalai Rainforests, Western Ghats (Davidar P, Parthasarathy N, eds). Final Technical Report, DoEn project, Pondicherry University, Pondicherry, pp 1-31.
  47. Polyakova O, Billor N. 2007. Impact of deciduous tree species on litterfall quality, decomposition rates and nutrient circulation in pine stands. For Ecol Manage 253: 11-18. https://doi.org/10.1016/j.foreco.2007.06.049
  48. Pragasan LA, Parthsarthy N. 2005. Litter production in tropical dry evergreen forests of south India in relation to season, plant life-forms and physiognomic groups. Current Science 88: 1255-1263.
  49. Proctor J. 1983. Tropical forest litter fall. I. Problems of data comparison. In: Tropical Rain Forest: Ecology and Management (Sutton SL, Whitmore TC, Chadwick AC, eds). Blackwell Scientific Publication, Oxford, pp 267-273.
  50. Proctor J. 1987. Nutrient cycling in primary and old secondary rainforests. Applied Geography 7: 135-152. https://doi.org/10.1016/0143-6228(87)90046-4
  51. Rai SN, Proctor J. 1986. Ecological Studies on Four Rainforests in Karnataka, India: II. Litterfall. J Ecol 74: 455-463. https://doi.org/10.2307/2260267
  52. Rajendraprasad M, Krishnan PN, Pushpangadan P. 2000. Vegetational characterization and litter dynamics of the sacred groves of Kerala, Southwest India. J Trop For Sci 12: 320-335.
  53. Rawat YS, Singh JS. 1988. Structure and Function of Oak Forests in Central Himalaya. I. Dry Matter Dynamics. Ann Bot 62: 397-411. https://doi.org/10.1093/oxfordjournals.aob.a087673
  54. Sahu KP, Singh L, Jhariya MK. 2013. Fine root biomass, forest floor and nutrient status of soil in an age series of teak plantation in dry tropics. The Bioscan 8: 1149-1152.
  55. Sanches L, Valentini CMA, Junior OBP, Nogueira JDS, Vourlitis GL, Biudes MS, Silva CJD, Bambi P, Lobo FDA. 2008. Seasonal and interannual litter dynamics of a tropical semideciduous forest of the southern Amazon Basin, Brazil. J Geophysical Res 113: 1-9.
  56. Shahi C, Sharma A, Bargali K, Bargali SS. 2014. Effect of disturbance gradient on forest floor biomass in natural forest ecosystems in and around Nainital. The Ecoscan 8: 163-168.
  57. Sharma SC, Pande PK. 1989. Patterns of litter nutrient concentration in some plantation ecosystems. For Ecol Manage 29: 151-163. https://doi.org/10.1016/0378-1127(89)90046-7
  58. Shi H, Singh A. 2002. An assessment of biodiversity hotspots using remote sensing and GIS. J Indian Society of Remote Sensing 30: 105-112. https://doi.org/10.1007/BF02989982
  59. Simard DG, Fyles JW, Paré D, Nguyen T. 2001. Impacts of clearcut harvesting and wildfire on soil nutrient status in the Quebec boreal forest. Can J Soil Sci 81: 229-237. https://doi.org/10.4141/S00-028
  60. Singh B, Tripathi KP, Singh K. 2011. Community Structure, Diversity, Biomass and Net Production in a Rehabilitated Subtropical Forest in North India. Open J Forestry 1: 11-26. https://doi.org/10.4236/ojf.2011.12003
  61. Singh KP. 1968. Litter production and nutrient turnover in deciduous forest of Varanasi. In: Proc Symp. Recent Advances in Tropical Ecology (Mishra R, Gopal B, eds). Varanasi, India, pp 655-665.
  62. Singh L, Singh JS. 1991. Species Structure, Dry Matter Dynamics and Carbon Flux of a Dry Tropical Forest in India. Ann Bot 68: 263-273. https://doi.org/10.1093/oxfordjournals.aob.a088252
  63. Singh L. 1992. Dry Matter and Nutrient Inputs through Litter Fall in a Dry Tropical Forest of India. Vegetatio 98: 129-140. https://doi.org/10.1007/BF00045551
  64. Singh L. 1995. Seasonal variation in biomass and nutrient content of the forest floor in a dry tropical forest. Oecologia Montana 4: 21-26.
  65. Sizer NC, Tanner EVJ, Kossmann Ferraz ID. 2000. Edge Effects on Litterfall Mass and Nutrient Concentrations in Forest Fragments in Central Amazonia. J Trop Ecol 16: 853-863. https://doi.org/10.1017/S0266467400001760
  66. Spain AV. 1984. Litterfall and the Standing Crop of Litter in Three Tropical Australian Rainforests. J Ecol 72: 947-961. https://doi.org/10.2307/2259543
  67. Sun Y, Wu J, Shao Y, Zhou L, Mai B, Lin Y, Fu S. 2011. Responses of soil microbial communities to prescribed burning in two paired vegetation sites in southern China. Ecol Res 26: 669-677. https://doi.org/10.1007/s11284-011-0827-2
  68. Sundarapandian SM, Swamy PS. 1999. Litter production and leaf-litter decomposition of selected tree species in tropical forests at Kodayar in the Western Ghats, India. For Ecol Manage 123: 231-244. https://doi.org/10.1016/S0378-1127(99)00062-6
  69. Swamy SL, Dutt CBS, Murthy MSR, Mishra A, Bargali SS. 2010. Floristics and dry matter dynamics of tropical wet evergreen forests of Western Ghats, India. Current Science 99: 353-364.
  70. Swift MJ, Russell-Smith A, Perfect TJ. 1981. Decomposition and Mineral-Nutrient Dynamics of Plant Litter in a Regenerating Bush-Fallow in Sub-Humid Tropical Nigeria. J Ecol 69: 981-995. https://doi.org/10.2307/2259649
  71. Tandon S, Sahu SK, Mishra ASP, Mishra PC. 2012. Litter disappearance in ash mound plantation site. The Ecoscan 1: 83-86.
  72. Tiwari SD, Joshi R. 2013. Litter decomposition and nutrient release pattern of some prominent tree species in the cool-temperate forests of the Nanda Devi Biosphere Reserve in Uttarakhand, India. Int J Conserv Sci 4: 329-336.
  73. Tripathi SK, Singh KP. 1995. Litter dynamics of recently harvested and mature bamboo savannas in a dry tropical region in India. J Trop Ecol 11: 403-417. https://doi.org/10.1017/S0266467400008865
  74. Tsutsumi T, Nishitani Y, Kirimura Y. 1983. On the effects of soil fertility on the rate and the nutrient element concentrations of litterfall in a forest. Jap J Ecol 33: 313-322.
  75. Visalakshi N. 1993. Litterfall, standing crop of litter and their nutrients in two tropical dry evergreen forests in India. Int J Ecol Environ Sci 19: 163-180.
  76. Vitousek PM, Sanford RL Jr. 1986. Nutrient cycling in moist tropical forest. Ann Rev Ecol Syst 17: 137-167. https://doi.org/10.1146/annurev.es.17.110186.001033
  77. Vogt KA, Grier CC, Vogt DJ. 1986. Production, Turnover, and Nutrient Dynamics of Above- and Belowground Detritus of World Forests. Advances Ecol Res 15: 303-377.
  78. Xuluc-Tolosa FJ, Vester HFM, Ramirez-Marcial N, Castellanos- Albores J, Lawrence D. 2003. Leaf litter decomposition of tree species in three successional phases of tropical dry secondary forest in Campeche, Mexico. For Ecol Manage 174: 401-412. https://doi.org/10.1016/S0378-1127(02)00059-2
  79. Yadav DK, Ghosh L, Jhariya MK. 2017. Forest Fragmentation and Stand Structure in Tropics: Stand Structure, Diversity and Biomass. Lap Lambert Academic Publishing. Heinrich-Bocking-Str. 6-8, 66121, Saarbrucken, Germany, pp 116. ISBN: 978-3-330-05287-1.
  80. Yadav DK, Jhariya MK. 2017. Tree Community Structure, Regeneration and Patterns of Diversity in Natural and Plantation Forest Ecosystem. Research in Environment and Life Sciences 10: 383-389.
  81. Yadav RS, Yadav BL, Chhipa BR. 2008. Litter dynamics and soil properties under different tree species in a semi-arid region of Rajasthan, India. Agroforestry Systems 73: 1-12. https://doi.org/10.1007/s10457-008-9106-9
  82. Yoda K, Kira T. 1969. Comparative ecological studies on three main types of forest vegetation in Thailand. 5. Accumulation and turnover of soil organic matter, with notes on the altitudinal soil sequence on Khao (Mt.) Luang, peninsular Thailand. Nature Life South-East Asia 6: 88-110.
  83. Zhou G, Liu S, Li Z, Zhang D, Tang X, Zhou C, Yan J, Mo J. 2006. Old-growth forests can accumulate carbon in soils. Science 314: 1417. https://doi.org/10.1126/science.1130168