Abstract
This study evaluated impacts of Coriaria nepalensis Wall. colonization on soil characteristics, vegetation structure and composition, regeneration status and expected future compositional changes, biomass and carbon stock in tree species of a mixed conifer forest of Central Himalaya. Three sites (1 ha each in an old landslide area) differing in Coriaria density (low: 20 individuals ha−1; medium: 120 indiv. ha−1; high: 190 indiv. ha−1) were used to enumerate the tree species. A total of 9 tree species and 2830 individuals were recorded from the three study sites that represented a gradient of Coriaria density. Number of species varied from 3 to 7 and the individuals from 690 to 1270 per site with lowest numbers at low Coriaria density and highest at medium Coriaria density. The number of seedlings increased with increasing Coriaria density, and the sites were unique in their seedling composition, indicating marked temporal dynamics. Site wise regeneration analysis showed that regeneration was poor at the site with low Coriaria density and good at the high-density site where many species emerged as seedlings. These results indicate that the ameliorative effects of Coriaria in terms of soil buildup, and accumulation of nutrients and organic matter helped more species to colonize the area. This facilitative ability of Coriaria can be used to restore degraded forest ecosystems of Indian Central Himalaya.
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References
Adhikari BS, Dhaila S, Rawat YS (1998) Structure of Himalayan moist temperate Cypress forest at and around Nainital, Kumaun Himalayas. Oecol Montana 7:21–31
Bargali K, Bargali SS (2009) Effect of phosphorus nutrition on growth and mycorrhizal dependency of Coriaria nepalensis seedlings. Nat Sci 7(6):19–24
Bargali K, Tewari A (2004) Growth and water relation parameters in drought stressed Coriaria nepalensis seedlings. J Arid Environ 58:505–512
Bargali SS, Tewari JC, Rawat YS, Singh SP (1987) Woody vegetation in high elevation blue—pine mixed oak forest of Kumaun Himalaya, India. In: Pangty YPS, Joshi SC (eds) Western Himalaya: environment, problems and development. Gyanodaya Parakashan, Nainital, pp 121–155
Bargali SS, Rana BS, Rikhari HC, Singh RP (1989) Population structure of Central Himalayan blue pine (Pinus wallichiana) forest. Environ Ecol 7:431–436
Bargali K, Joshi B, Goel D (2003) Impact on soil characteristic and understory vegetation of Coriaria nepalensis in natural landslide area. Ecoprint 10(1):43–46
Bargali K, Bisht P, Khan A, Rawat YS (2013) Diversity and regeneration status of tree species at Nainital Catchment, Uttarakhand, India. Int J Biodivers Conserv 5:270–280
Bargali K, Maurya NR, Bargali SS (2015) Effect of a nitrogen-fixing actinorhizal shrub on herbaceous vegetation in a mixed conifer forest of Central Himalaya. Curr World Environ 10(3):957–966
Barker G, Odling-Snee J (2014) Integrating ecology and evolution: niche construction and ecological engineering. In: Baker G, Deojardins E, Pearce T (eds) Entangled life. Springer, Dordrecht, pp 187–211
Berke SK (2010) Functional groups of ecosystem engineers: a proposed classification with comments on current issues. Integr Comp Biol 50:147–157
Black CA (1968) Soil plant relations. Wiley, New York
Brooker RW (2006) Plant–plant interactions and environmental change. New Phytol 171:271–289
Clarkson BR, Clarkson BD (1995) Recent vegetation changes on Mount Tarawera Rotorua, New Zealand. NZ J Bot 33:339–354
Curtis JT (1959) The vegetation of Wisconsin. University of Wisconsin Press, Madison
Curtis JT, McIntosh RP (1950) The interrelations of certain analytic and synthetic phytosociological characters. Ecology 31:434–455
Gosain BG, Negi GCS, Dhyani PP, Bargali SS, Saxena R (2015) Ecosystem services of forests: carbon stock in vegetation and soil components in a watershed of Kumaun Himalaya, India. Int J Ecol Environ Sci 41(3–4):177–188
Hasui E, Silva VX, Cunha RGT, Ramos FN, Ribeiro MC, Sacramento M, Coelho MTP, Pereira DGS, Ribeiro BR (2017) Additions of landscape metrics improve predictions of occurrence of species distribution models. J For Res 28(5):963–974
Jones CG, Cutierrez JL, Groffman PM, Shachak M (2006) Linking ecosystem engineers to soil processes: a framework using the Jenny State Factor Equation. Eur J Soil Biol 42(supplement 1):S39–S53
Joshi B, Singh SP, Rawat YS, Goel D (2001) Facilitative effect of Coriaria nepalensis on species diversity and growth of herbs on severely eroded hill slopes. Curr Sci 80(5):678–682
Kagan TP, Zaady E, Shachak M, Karnieli A (2016) Transformation of shrub lands to forests: the role of woody species as ecosystem engineers and landscape modulators. For Ecol Manag 361:257–268
Kharkwal G, Rawat YS, Pangtey YS (2009) An ordination of the forest communities in Nainital catchment of Kumaun Himalaya. J Environ Biol 30(5):853–857
Kittur B, Swamy SL, Bargali SS, Jhariya MK (2014) Wildland fires and moist deciduous forests of Chhattisgarh, India: divergent component assessment. J For Res 25(4):857–866
Knight DH (1975) A phytosociological analysis of species-rich tropical forest on Barro Colorado Island, Panama. Ecol Monogr 45:259–284
Lambdon PW, Pyšek P, Basnou C, Hejda M, Arianoutsou M, Essl F, Jarošík V, Pergl J, Winter M, Anastasiu P, Andriopoulos P, Bazos I, Brundu G, Celesti-Grapow L, Chassot P, Delipetrou P, Josefsson M, Kark S, Klotz S, Kokkoris Y, Kühn I, Marchante H, Perglová I, Pino J, Vilá M, Zikos A, Hulme PE (2008) Alien flora of Europe: species diversity, temporal trends, geographical patterns and research need. Preslia 80:101–149
Lorena GA, Gomez JM, Zamora R, Boettinger JL (2005) Canopy vs soil effects of shrubs facilitating tree seedlings in Mediterranean montane ecosystems. J Veg Sci 16:191–198
Mishra G, Das PK, Borah R, Dutta A (2017) Investigation of phytosociological parameters and physico-chemical properties of soil in tropical semi- evergreen forests of Eastern Himalaya. J For Res 28(3):513–520
Naudiyal N, Schmerbeck J (2017) The changing Himalayan landscape: pine-oak forest dynamics and the supply of ecosystem services. J For Res 28(3):431–443
Oakley BB, North MP, Franklin JF (2006) Facilitative and competitive effects of a N-fixing shrubs on white fir saplings. For Ecol Manag 233:100–107
Padilla FM, Pugnaire FI (2006) The role of nurse plants in the restoration of degraded environments. Front Ecol Environ 4:196–202
Pearce T (2011) Ecosystem engineering, experiment and evolution. Biol Philos 26:793–812
Phillips EA (1959) Method of vegetation study. Holt Rinehart and Winston, Inc., New York
Pielou EC (1966) Species diversity and pattern diversity in the study of ecological succession. J Theor Biol 10:370–383
Rana S, Bargali K, Bargali SS (2015) Assessment of plant diversity, regeneration status, biomass and carbon stock in a Central Himalayan cypress forest. Int J Biodivers Conserv 7(6):321–329
Shankar Uma (2001) A case of high tree diversity in a Sal (Shorea robusta) dominated lowland forest of Eastern Himalaya: floristic composition, regeneration and conservation. Curr Sci 81:776–786
Shannon CE, Weiner W (1963) The mathematical theory of communication. University of Illinois Press, Urbana
Shumway SW (2000) Facilitative effects of a sand dune shrub on species growing beneath the shrub canopy. Oecologia 124:138–148
Simpson EH (1949) Measurement of diversity. Nature 163:688
Singh JS, Singh SP (1987) Forest vegetation of Himalaya. Bot Rev 53:80–192
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. Curr Sci 99(3):353–364
Tsheboeng G, Murray-Hudson M, Kashe K (2017) Regeneration status of riparian tree species in two sites that differ in land use in the Oakvango delta, Botswana. J For Res 28(5):1073–1082
Valdiya KS (1980) Geology of Kumaun Lesser Himalaya. Wadia Institute of Himalayan Geology, Dehradun
Van Steenis CGGJ (1958) Rejuvenation as a factor for judging the status of vegetation types. The biological nomad theory. In: Proceedings of the Kandy symposium on study of tropical vegetation. UNESCO, Paris, pp 159–163
Werner C, Zumkier U, Beyschleg W, Maguas C (2010) High competitiveness of a resource demanding Acacia under low resource supply. Plant Ecol 206:83–96
West DC, Shugart JHH, Ranney JW (1981) Population structure of forest over a large area. For Sci 27:701–710
Whittaker RH (1972) Evolution and measurement of species diversity. Taxon 21:213–251
Wright JP, Jones CG, Boeken B, Shachak M (2006) Predictability of ecosystem engineering effects on species richness across environmental variability and spatial scales. J Ecol 94:815–824
Mueller-Dombois D, Ellenburg H (1974) Aims and methods of vegetation ecology. Wiley, Hoboken
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Project funding: The work was partially supported by a project grant from University Grant Commission, New Delhi.
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Corresponding editor: Tao Xu.
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Mourya, N.R., Bargali, K. & Bargali, S.S. Impacts of Coriaria nepalensis colonization on vegetation structure and regeneration dynamics in a mixed conifer forest of Indian Central Himalaya. J. For. Res. 30, 305–317 (2019). https://doi.org/10.1007/s11676-018-0613-x
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DOI: https://doi.org/10.1007/s11676-018-0613-x