Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-17T10:40:59.971Z Has data issue: false hasContentIssue false

Natural disturbance and soils drive diversity and dynamics of seasonal dipterocarp forest in Southern Thailand

Published online by Cambridge University Press:  06 May 2019

Sarayudh Bunyavejchewin
Affiliation:
Forest Research Office, Department of National Parks, Wildlife and Plant Conservation, Bangkok 10900, Thailand; and Department of Forest Biology, Faculty of Forestry, Kasetsart University, Chatuchak, Bangkok 10900, Thailand
Aroon Sinbumroong
Affiliation:
Royal Forest Department, Bangkok 10900, Thailand
Benjamin L. Turner
Affiliation:
Smithsonian Tropical Research Institute, Apartado 0843-03092, Balboa, Ancon, Republic of Panama
Stuart J. Davies*
Affiliation:
Center for Tropical Forest Science-Forest Global Earth Observatory, Smithsonian Tropical Research Institute, P.O. Box 37012, Washington 20013, USA
*

Abstract

In 2000, we established a 24-ha plot in Peninsular Thailand to investigate how forest composition, structure and dynamics vary with spatial heterogeneity in resource availability. Detailed soil and topographic surveys were used to describe four edaphic habitats in the plot. Disturbance history was inferred from historical records and floristic analysis. The plot included >119 000 trees ≥1 cm dbh in 578 species, and was recensused in 2010. Species distributions, floristic turnover, stand structure, demographic rates and biomass dynamics were strongly influenced by heterogeneity in soils, topography and disturbance history. Over 75% of species were aggregated on specific edaphic habitats leading to strong compositional turnover across the plot. Soil chemistry more strongly affected species turnover than topography. Forest with high biomass and slow dynamics occurred on well-drained, low fertility ridges. The distribution and size structure of pioneer species reflected habitat-specific differences in disturbance history. Overall, above-ground biomass (AGB) increased by 0.64 Mg ha−1 y−1, from 385 to 392 Mg ha−1, an increase that was entirely attributable to recovery after natural disturbance. Forest composition and stand structure, by reflecting local disturbance history, provide insights into the likely drivers of AGB change in forests. Predicting future changes in tropical forests requires improved understanding of how soils and disturbance regulate forest dynamics.

Type
Research Article
Copyright
© Cambridge University Press 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allie, E, Pelissier, R, Engel, J, Petronelli, P, Freycon, V, Deblauwe, V, Soucemarianadin, L, Weigel, J and Baraloto, C (2015) Pervasive local-scale tree-soil habitat association in a tropical forest community. PLoS ONE 10, e0141488.CrossRefGoogle Scholar
Anderson-Teixeira, KJ, Davies, SJ, Bennett, AC, Gonzalez-Akre, EB, Muller-Landau, HC, Wright, SJ, et al. (2015) CTFS-ForestGEO: a worldwide network monitoring forests in an era of global change. Global Change Biology 21, 528–49.CrossRefGoogle Scholar
Ashton, PS (1995) Towards a regional forest classification for the humid tropics of Asia. In EO, Box (ed.), Vegetation Science in Forestry. Dordrecht: Kluwer Academic, pp. 453464.Google Scholar
Ashton, PS (2015) On the Forests of Tropical Asia: Lest the Memory Fade. Kew: Royal Botanic Gardens, 670 pp.Google Scholar
Ashton, PS and Hall, P (1992) Comparisons of structure among mixed dipterocarp forests of north-western Borneo. Journal of Ecology 80, 459481.CrossRefGoogle Scholar
Baillie, IC, Bunyavejchewin, S, Kaewfoo, M, Baker, PJ and Hallett, SH (2018) Stoichiometry of cationic nutrients in Phaeozems derived from skarn and Acrisols from other parent materials in lowland forests of Thailand. Geoderma Regional 12, 19.CrossRefGoogle Scholar
Baker, PJ, Bunyavejchewin, S, Oliver, CD and Ashton, PS (2005) Disturbance history and historical stand dynamics of a seasonal tropical forest in western Thailand. Ecological Monographs 75, 317343.CrossRefGoogle Scholar
Baldeck, CA, Harms, KE, Yavitt, JB, John, R, Turner, BL, Valencia, R, Navarrete, H, Davies, SJ, Chuyong, GB, Kenfack, D, Thomas, DW, Madawala, S, Gunatilleke, N, Gunatilleke, S, Bunyavejchewin, S, Kiratiprayoon, S, Yaacob, A, Supardi, MN and Dalling, JW (2013) Soil resources and topography shape local tree community structure in tropical forests. Proceedings of the Royal Society B 280, 20122532.Google ScholarPubMed
Baltzer, JL and Davies, SJ (2012) Rainfall seasonality and pest pressure as determinants of tropical tree species’ distributions. Ecology and Evolution 2, 26822694.CrossRefGoogle ScholarPubMed
Baltzer, JL, Davies, SJ, Kassim, AR, Noor, NS and LaFrankie, JV (2007) Geographic distributions in tropical trees: can geographic range predict performance and habitat association in co-occurring tree species? Journal of Biogeography 34, 19161926.CrossRefGoogle Scholar
Brienen, RJ, Phillips, OL, Feldpausch, TR, Gloor, E, Baker, TR, Lloyd, J, et al. (2015) Long-term decline of the Amazon carbon sink. Nature 519, 344348.CrossRefGoogle ScholarPubMed
Bunyavejchewin, S, Baker, PJ and Davies, SJ (2011) Seasonally dry tropical forests in continental Southeast Asia: structure, composition, and dynamics. In McShea, WJ, Davies, SJ, and Bhumpakphan, N (eds), The Ecology and Conservation of Seasonally Dry Forest in Asia. Washington, DC: Smithsonian Institution Scholarly Press, pp. 935.Google Scholar
Chadwick, KD and Asner, GP (2016) Tropical soil nutrient distributions determined by biotic and hillslope processes. Biogeochemistry 127, 273289.CrossRefGoogle Scholar
Chambers, JQ, Negron-Juarez, RI, Marra, DM, Vittorioa, AD, Tewse, J, Roberts, D, Ribeiro, GHPM, Trumbore, SE and Higuchi, N (2013) The steady-state mosaic of disturbance and succession across an old-growth Central Amazon forest landscape. Proceedings of the National Academy of Sciences USA 110, 39493954.CrossRefGoogle ScholarPubMed
Chave, J, Andalo, C, Brown, S, Cairns, MA, Chambers, JQ, Eamus, D, Folster, H, Fromard, F, Higuchi, N, Kira, T, Lescure, J-P, Nelson, BW, Ogawa, H, Puig, H, Riera, B and Yamakura, T (2005) Tree allometry and improved estimation of carbon stocks and balance in tropical forests. Oecologia 145, 8799.CrossRefGoogle ScholarPubMed
Chave, J, Condit, R, Muller-Landau, HC, Thomas, SC, Ashton, PS, Bunyavejchewin, S, et al. (2008) Assessing evidence for a pervasive alteration in tropical tree communities. PLoS Biology 6, 18.CrossRefGoogle ScholarPubMed
Chave, J, Coomes, D, Jansen, S, Lewis, SL, Swenson, NG and Zanne, AE (2009) Towards a worldwide wood economics spectrum. Ecology Letters 12, 351366.CrossRefGoogle ScholarPubMed
Chazdon, RL (2003) Tropical forest recovery: legacies of human impact and natural disturbances. Perspectives in Plant Ecology, Evolution and Systematics 6, 5171.CrossRefGoogle Scholar
Chisholm, RA, Condit, R, Rahman, KA, Baker, PJ, Bunyavejchewin, S, et al. (2014) Temporal variability of forest communities: empirical estimates of population change in 4000 tree species. Ecology Letters 17, 855865.CrossRefGoogle ScholarPubMed
Cobbing, EJ (2011) Granitic rocks. In Ridd, MF, Barber, AJ, and Crow, MJ (eds), The Geology of Thailand. London: Geological Society, pp. 441457.CrossRefGoogle Scholar
Condit, R (1998) Tropical Forest Census Plots: Methods and Results from Barro Colorado Island, Panama and a Comparison with Other Plots. Berlin: Springer-Verlag, 211 pp.CrossRefGoogle Scholar
Condit, R, Aguilar, S, Hernandez, A, Perez, R, Lao, S, Angehr, G, Hubbell, SP and Foster, RB (2004) Tropical forest dynamics across a rainfall gradient and the impact of an El Niño dry season. Journal of Tropical Ecology 20, 5172.CrossRefGoogle Scholar
Condit, R, Ashton, PS, Baker, P, Bunyavejchewin, S, Gunatilleke, S, Gunatilleke, N, Hubbell, SP, Foster, RB, Itoh, A, LaFrankie, JV, Lee, HS, Losos, E, Manokaran, N, Sukumar, R and Yamakura, T (2000) Spatial patterns in the distribution of tropical trees. Science 288, 14141418.CrossRefGoogle Scholar
Condit, R, Ashton, PS, Manokaran, N, LaFrankie, JV, Hubbell, SP and Foster, RB (1999) Dynamics of the forest communities at Pasoh and Barro Colorado: comparing two 50 ha plots. Philosophical Transactions of the Royal Society, London, Series B 354, 17391748.CrossRefGoogle ScholarPubMed
Davies, SJ and Becker, P (1996) Floristic composition and stand structure of mixed dipterocarp and heath forests in Brunei Darussalam. Journal of Tropical Forest Science 8, 542569.Google Scholar
Davies, SJ, Nur Supardi, MN, LaFrankie, JV and Ashton, PS (2003) The trees of Pasoh Forest: stand structure and floristic composition of the 50-hectare forest research plot. In Okuda, T, Manokaran, N, Thomas, SC, and Ashton, PS (eds), Pasoh: Ecology and Natural History of a Southeast Asian Lowland Tropical Rain Forest. Tokyo: Springer, pp. 3550.CrossRefGoogle Scholar
Davies, SJ, Tan, S, LaFrankie, JV and Potts, MD (2005) Soil-related floristic variation in a hyperdiverse dipterocarp forest. In Roubik, D, Sakai, S, and Hamid Karim, AA (eds), Pollination Ecology and the Rain Forest (Sarawak Studies). New York, NY: Springer Science, pp. 2234.CrossRefGoogle Scholar
Feeley, KJ, Davies, SJ, Ashton, PS, Bunyavejchewin, S, Nur Supardi, MN, Kassim, AR, Tan, S and Chave, J (2007) The role of gap phase processes in the biomass dynamics of tropical forests. Proceedings of the Royal Society B 274, 28572864.CrossRefGoogle ScholarPubMed
Gardner, S, Sidisunthorn, P and Chayamarit, K (2015) Forest Trees of Southern Thailand, Volumes 1 and 2. Bangkok: Chulalongkorn University Book Center.Google Scholar
Gardner, S, Sidisunthorn, P and Chayamarit, K (2016) Forest Trees of Southern Thailand, Volume 2. Bangkok: Chulalongkorn University Book Center.Google Scholar
Gloor, M, Phillips, OL, Lloyd, JJ, Lewis, SL, Malhi, Y, Baker, TR, et al. (2009) Does the disturbance hypothesis explain the biomass increase in basin-wide Amazon forest plot data? Global Change Biology 15, 24182430.CrossRefGoogle Scholar
Gunatilleke, CVS, Gunatilleke, IAUN, Esufali, S, Harms, KE, Ashton, PMS, Burslem, DFRP and Ashton, PS (2006) Species–habitat associations in a Sri Lankan dipterocarp forest. Journal of Tropical Ecology 22, 371384.CrossRefGoogle Scholar
Harms, KE, Condit, R, Hubbell, SP and Foster, RB (2001) Habitat associations of trees and shrubs in a 50-ha Neotropical forest plot. Journal of Ecology 89, 947959.CrossRefGoogle Scholar
Harrison, RD, Tan, S, Plotkin, JB, Slik, F, Detto, M, Brenes, T, Itoh, A and Davies, SJ (2013) Consequences of defaunation for a tropical tree community. Ecology Letters 16, 687694.CrossRefGoogle ScholarPubMed
Hendershot, WH, Lalande, H and Duquette, M (2008) Ion exchange and exchangeable cations. In Carter, MR, and Gregorich, E (eds), Soil Sampling and Methods of Analysis. Boca Raton, FL: Canadian Society of Soil Science and CRC Press, pp. 173178.Google Scholar
Hogan, JA, Zimmerman, JK, Uriarte, M, Turner, BL, Thompson, J and Nardoto, GB (2016) Land-use history augments environment-plant community relationship strength in a Puerto Rican wet forest. Journal of Ecology 104, 14661477.CrossRefGoogle Scholar
Ickes, K, DeWalt, S and Appanah, S (2001) Effects of native pigs (Sus scrofa) on woody understorey vegetation in a Malaysian lowland rain forest. Journal of Tropical Ecology 17, 191206.CrossRefGoogle Scholar
John, R, Dalling, JW, Harms, KE, Yavitt, JB, Stallard, RF, Mirabello, M, Hubbell, SP, Valencia, R, Navarrete, H, Vallejo, M and Foster, RB (2007) Soil nutrients influence spatial distributions of tropical tree species. Proceedings of the National Academy of Sciences USA 104, 864869.CrossRefGoogle ScholarPubMed
Katabuchi, M, Wright, SJ, Swenson, NG, Feeley, KJ, Condit, R, Hubbell, SP and Davies, SJ (2017) Contrasting outcomes of species- and community-level analyses of the temporal consistency of functional composition. Ecology 98, 22732280.CrossRefGoogle ScholarPubMed
Kurten, EL, Bunyavejchewin, S and Davies, SJ (2018) Phenology of a dipterocarp forest with seasonal drought: insights into the origin of general flowering. Journal of Ecology 106, 126136.CrossRefGoogle Scholar
Lee, HS, Davies, SJ, LaFrankie, JV, Tan, S, Itoh, A, Yamakura, T, Ohkubo, T and Ashton, PS (2002) Floristic and structural diversity of 52 hectares of mixed dipterocarp forest in Lambir Hills National Park, Sarawak, Malaysia. Journal of Tropical Forest Science 14, 379400.Google Scholar
Legendre, P and Legendre, L (1998) Numerical Ecology. Second edition. Amsterdam: Elsevier.Google Scholar
Lewis, SL, Lopez-Gonzalez, G, Sonke, B, Affum-Baffoe, K, Baker, TR, Ojo, LO, et al. (2009) Increasing carbon storage in intact African tropical forests. Nature 457, 10031006.CrossRefGoogle ScholarPubMed
Luskin, MS, Brashares, JS, Ickes, K, Sun, IF, Fletcher, C, Wright, SJ and Potts, MD (2017) Cross-boundary subsidy cascades from oil palm degrade distant tropical forests. Nature Communications 8, 22312237.CrossRefGoogle ScholarPubMed
Malhi, Y, Baker, TR, Phillips, OL, Almeida, S, Alvarez, E, Arroyo, L, et al. (2004) The above-ground coarse wood productivity of 104 Neotropical forest plots. Global Change Biology 10, 563591.CrossRefGoogle Scholar
Manokaran, N, LaFrankie, JV, Kochummen, KM, Quah, ES, Klahn, JE, Ashton, PS and Hubbell, SP (1990) Methodology for the Fifty-hectare Research Plot at Pasoh Forest Reserve. Kepong: Forest Research Institute Malaysia.Google Scholar
McMichael, CN, Matthews-Bird, F, Farfan-Rios, W and Feeley, KJ (2017) Ancient human disturbances may be skewing our understanding of Amazonian forests. Proceedings of the National Academy of Sciences USA 114, 522527.CrossRefGoogle ScholarPubMed
Ogawa, H, Yoda, K, Kira, T, Ogino, K, Shidei, T, Ratanawongse, D and Apasutaya, C (1965) Comparative ecological study on three main types of forest vegetation in Thailand I. Structure and floristic composition. Nature and Life in Southeast Asia 4, 1348.Google Scholar
Phillips, OL, Malhi, Y, Higuchi, N, Laurance, WF, Nunez, PV, Vasquez, RM, Laurance, SG, Ferreira, LV, Stern, M, Brown, S and Grace, J (1998) Changes in the carbon balance of tropical forests: evidence from long-term plots. Science 282, 439442.CrossRefGoogle ScholarPubMed
Poorter, L, Bongers, F, Aid, TM, Almeyda Zambran, AM, Balvanera, P, Becknell, JM, et al. (2016) Biomass resilience of Neotropical secondary forests. Nature 530, 211214.CrossRefGoogle ScholarPubMed
Pyke, CR, Condit, R, Aguilar, S and Lao, S (2001) Floristic composition across a climatic gradient in a Neotropical lowland forest. Journal of Vegetation Science 12, 553566.CrossRefGoogle Scholar
Qie, L, Lewis, SL, Sullivan, MJP, Lopez-Gonzalez, G, Pickavance, GC, Sunderland, T, et al. (2017) Long-term carbon sink in Borneo’s forests halted by drought and vulnerable to edge effects. Nature Communications 8, 19661976.CrossRefGoogle ScholarPubMed
Roberts, MR and Gilliam, FS (1995) Disturbance effects on herbaceous layer vegetation and soil nutrients in Populus forests of northern lower Michigan. Journal of Vegetation Science 6, 903912.CrossRefGoogle Scholar
Russo, SE, Cannon, WL, Elowsky, C, Tan, S and Davies, SJ (2010) Variation in leaf stomatal traits of 28 tree species in relation to gas exchange along an edaphic gradient in a Bornean rain forest. American Journal of Botany 97, 11091120.CrossRefGoogle Scholar
Russo, SE, Davies, SJ, King, DA and Tan, S (2005) Soil-related performance variation and distributions of tree species in a Bornean rain forest. Journal of Ecology 93, 879889.CrossRefGoogle Scholar
Schietti, J, Emilio, T, Rennó, CD, Drucker, DP, Costa, FRC, Nogueira, A, Baccaro, FB, Figueiredo, F, Castilho, CV, Kinupp, V, Guillaumet, J-L, Garcia, ARM, Lima, AP and Magnusson, WE (2013) Vertical distance from drainage drives floristic composition changes in an Amazonian rainforest. Plant Ecology and Diversity 7, 241253.CrossRefGoogle Scholar
Schnitzer, SA and Bongers, F (2011) Increasing liana abundance and biomass in tropical forests: emerging patterns and putative mechanisms. Ecology Letters 14, 397406.CrossRefGoogle ScholarPubMed
Shiels, AB and Walker, LR (2013) Landslides cause spatial and temporal gradients at multiple scales in the Luquillo Mountains of Puerto Rico. Ecological Bulletins 54, 211221.Google Scholar
Thai Meteorological Department (2016) Records of tropical cyclone hit Thailand in 66-years period (1951–2016). Bangkok: Climatological Center, Meteorological Development Bureau, Thai Meteorological Department.Google Scholar
Tuomisto, H, Ruokolainen, K and Yli-Halla, M (2003) Dispersal, environment, and floristic variation of western Amazonian forests. Science 299, 241244.CrossRefGoogle ScholarPubMed
Turner, BL, Brenes-Arguedas, T and Condit, R (2018) Pervasive phosphorus limitation of tree species but not communities in tropical forests. Nature 555, 367370.CrossRefGoogle Scholar
Valencia, R, Condit, R, Muller-Landau, HC, Hernandez, C and Navarrete, H (2009) Dissecting biomass dynamics in a large Amazonian forest plot. Journal of Tropical Ecology 25, 473482.CrossRefGoogle Scholar
Valencia, R, Foster, RB, Villa, G, Condit, R, Svenning, JC, Hernández, C, Romoleroux, K, Losos, E, Magård, E and Balslev, H (2004) Tree species distributions and local habitat variation in the Amazon: large forest plot in eastern Ecuador. Journal of Ecology 92, 214229.CrossRefGoogle Scholar
van Steenis, CGGJ (1950) The delimitation of Malaysia and its main geographical divisions. Flora Malesiana 1, lxxlxxv.Google Scholar
Walker, LR, Shiels, AB, Bellingham, PJ, Sparrow, AD, Fetcher, N, Landau, FH, Lodge, DJ and Kitzberger, T (2013) Changes in abiotic influences on seed plants and ferns during 18 years of primary succession on Puerto Rican landslides. Journal of Ecology 101, 650661.CrossRefGoogle Scholar
Weintraub, SR, Taylor, PG, Porder, S, Cleveland, CC, Asner, GP and Townsend, AR (2015) Topographic controls on soil nitrogen availability in a lowland tropical forest. Ecology 96, 15611574.CrossRefGoogle Scholar
Woodruff, DS (2003) Neogene marine transgressions, palaeogeography and biogeographic transitions on the Thai-Malay Peninsula. Journal of Biogeography 30, 551567.CrossRefGoogle Scholar
Wright, SJ (2013) The carbon sink in intact tropical forests. Global Change Biology 19, 337339.CrossRefGoogle ScholarPubMed
Yap, SL, Davies, SJ and Condit, R (2016) Dynamic response of a Philippine dipterocarp forest to typhoon disturbance. Journal of Vegetation Science 27, 133143.CrossRefGoogle Scholar
Zimmerman, JK, Everham, EM, Waide, RB, Lodge, DJ, Taylor, CM and Brokaw, NVL (1994) Responses of tree species to hurricane winds in subtropical wet forest in Puerto Rico: implications for tropical tree life histories. Journal of Ecology 82, 911922.CrossRefGoogle Scholar