Forest Restoration in an Abandoned Seasonally Dry Tropical Forest in the Mae Klong Watershed, Western Thailand 10.32526/ennrj/21/20230121

Main Article Content

Ritthikai Saikhammoon
Sarawood Sungkaew
Sathid Thinkampaeng
Wongsatorn Phumphuang
Torlarp Kamyo
Dokrak Marod

Abstract

Deforestation for the development of agricultural land is a critical driver of biodiversity loss. We examined the relationships between tree species and environments after the abandonment of a plot of land at the Mae Klong Watershed Research Station, Western Thailand. Vegetation monitoring was conducted every two years on a 16-ha permanent plot established in 2011 until 2019. All trees with diameter at breast height (DBH)≤1 cm were measured. Canonical correspondence analysis (CCA) was performed to investigate the relationships between tree species and environments. We found a total of 199 tree species in the plot, which comprised both pioneer and climax species. The high tree density and low basal area were 1,280 stem/ha and 7.30 m2/ha, respectively. During 2011-2019, the species richness and total tree density were decreased by nine species (from 206 to 197 species) and 83 stem/ha (from 1,120 to 1,037 stem/ha). In contrast, the total basal area increased from 6.41 to 7.26 stem/ha. According to the measured environmental variables, mixed deciduous species such as Pterocarpus macrocarpus and Xylia xylocarpa var. kerrii preferred higher elevations and drier sites compared to dry evergreen species such as Dipterocarpus alatus. Early colonizing species such as Trema orientalis and Ficus species exhibited rapid population decreases, whereas climax species such as Lagerstroemia tomentosa exhibited highly successful regeneration under natural conditions. Artificial reforestation efforts may be required in areas with large disturbance, including the planting of mixed tree species to promote natural regeneration and reduce the recovery period.

Article Details

How to Cite
Saikhammoon, R., Sungkaew, S., Thinkampaeng, S., Phumphuang, W., Kamyo, T., & Marod, D. (2023). Forest Restoration in an Abandoned Seasonally Dry Tropical Forest in the Mae Klong Watershed, Western Thailand: 10.32526/ennrj/21/20230121. Environment and Natural Resources Journal, 21(5), 443–457. Retrieved from https://ph02.tci-thaijo.org/index.php/ennrj/article/view/249615
Section
Original Research Articles

References

Aide TM, Zimmerman JK, Pascarella JB, Rivera L, Marcano-Vega H. Forest regeneration in a chronosequence of tropical abandoned pastures: Implications for restoration ecology. Restoration Ecology 2000;8(4):328-38.

Albrecht L, Stallard RF, Kalko EK. Land use history and population dynamics of free-standing figs in a maturing forest. PLoS ONE 2017;12(5):e0177060.

Allison L. Organic carbon. In: Black CA, editor. Methods of Soil Analysis: Part 2 Chemical and Microbiological Properties. Wisconsin: American Society of Agronomy; 1965. p. 1367-78.

Bagousse‐Pinguet Y, Xiao S, Brooker RW, Gross N, Liancourt P, Straile D, et al. Facilitation displaces hotspots of diversity and allows communities to persist in heavily stressed and disturbed environments. Journal of Vegetation Science 2014;25(1):66-76.

Beck R. Soil Analysis Handbook of Reference Methods. New York, USA: CRC Press; 1999.

Boeschoten LE, van Breugel M, Bailon M, Balbuena J, Nuñez M, Cerezo A, et al. Framework species approach proves robust in restoring forest on fire prone invasive grass: A case study from Panama. Journal of Sustainable Forestry 2021;40(2):197-215.

Bray RH, Kurtz LT. Determination of total, organic, and available forms of phosphorus in soils. Soil Science 1945;59(1):39-46.

Chaiyo U, Garivait S, Wanthongchai K. Structure and carbon storage in aboveground biomass of mixed deciduous forest in western region, Thailand. GMSARN International Journal 2012;6:143-50.

Chapman HD. Cation exchange capacity. In: Black CA, Evans DD, White JL, Ensminger LE, Clark FE, Dinauer DC, editors. Method of Soil Analysis, Part 2: Chemical and Microbiological Properties. Madison (WI): The American Society of Agronomy; 1965. p. 891-913.

Chave J, Condit R, Muller-Landau HC, Thomas SC, Ashton PS, Bunyavejchewin S, et al. Assessing evidence for a pervasive alteration in tropical tree communities. PLoS Biology 2008;6(3):e45.

Chazdon RL. Tropical forest recovery: Legacies of human impact and natural disturbances. Perspectives in Plant Ecology, Evolution and Systematics 2003;6(1-2):51-71.

Chazdon RL. Second Growth. Chicago: University of Chicago Press; 2014.

Chen X, Wang X, Li J, Kang D. Species diversity of primary and secondary forests in Wanglang Nature Reserve. Global Ecology and Conservation 2020;22:e01022.

Collins LM, Schafer JL, Kam CM. A comparison of inclusive and restrictive strategies in modern missing data procedures. Psychological Methods 2001;6(4):Article No. 330.

Curtis PG, Slay CM, Harris NL, Tyukavina A, Hansen MC. Classifying drivers of global forest loss. Science 2018; 361(6407):1108-11.

Delgado-Baquerizo M, Reich PB, Trivedi C, Eldridge DJ, Abades S, Alfaro FD, et al. Multiple elements of soil biodiversity drive ecosystem functions across biomes. Nature Ecology and Evolution 2020;4(2):210-20.

Du H, Hu F, Zeng F, Wang K, Peng W, Zhang H, et al. Spatial distribution of tree species in evergreen-deciduous broadleaf karst forests in Southwest China. Scientific Reports 2017;7(1):1-9.

Elliott S, Navakitbumrung P, Kuarak C, Zangkum S, Anusarnsunthorn V, Blakesley D. Selecting framework tree species for restoring seasonally dry tropical forests in Northern Thailand based on field performance. Forest Ecology and Management 2003;184(1-3):177-91.

Fagundes M, Weisser W, Ganade G. The role of nurse successional stages on species‐specific facilitation in drylands: Nurse traits and facilitation skills. Ecology and Evolution 2018;8(10):5173-84.

Food and Agriculture Organization of the United Nation (FAO), United Nation Environment Programme (UNEP). The State of the World’s Forests 2020: Forests, Biodiversity and People. Rome, Italy: FAO; 2020.

Geist HJ, Lambin EF. Proximate causes and underlying driving forces of tropical deforestation tropical forests are disappearing as the result of many pressures, both local and regional, acting in various combinations in different geographical locations. BioScience 2002;52(2):143-50.

Good SP, Noone D, Bowen G. Hydrologic connectivity constrains partitioning of global terrestrial water fluxes. Science 2015;349(6244):175-7.

Goodale UM, Ashton MS, Berlyn GP, Gregoire TG, Singhakumara BMP, Tennakoon KU. Disturbance and tropical pioneer species: Patterns of association across life history stages. Forest Ecology and Management 2012;277(1):54-66.

Gravel D, Canham CD, Beaudet M, Messier C. Shade tolerance, canopy gaps and mechanisms of coexistence of forest trees. Oikos 2010;119(3):475-84.

Gustafsson N, Culley S, Ashdown G, Owen DM, Pereira PM, Henriques R. Fast live-cell conventional fluorophore nanoscopy with ImageJ through super-resolution radial fluctuations. Nature Communications 2016;7(1):Article No. 12471.

Hansen MC, DeFries RS. Detecting long-term global forest change using continuous fields of tree-cover maps from 8-km advanced very high resolution radiometer (AVHRR) data for the years 1982-99. Ecosystems 2004;7(7):695-716.

Hooker TD, Compton JE. Forest ecosystem carbon and nitrogen accumulation during the first century after agricultural abandonment. Ecological Applications 2003;13(2):299-313.

Kamyo T. Gep-Informatics Modeling on Tropical Seasonal Forest Dynamics in Mae Klong Watershed Research Station, Kanchanaburi Province [dissertation]. Bangkok, Kasetsart University; 2016.

Kamyo T, Thinkampaeng S, Panuthai S, Tanaka H, Marod D. Natural forest regeneration in abandoned areas in Mae Klong Watershed Research Station Thong PhaPhoom District, Kanchanaburi Province. Proceedings of the 2nd Thai Forest Ecological Research Network Conference; 2013 Jan 24-26; Maejo University, Chiangmai: Thailand; 2013 (in Thai).

Kamyo T, Marod D, Pattanakiat S, Suksawang S, Panuthai S. Land cover changes in tropical seasonal forests at Mae Klong head watershed, Kanchanaburi Province, Thailand. Maejo International Journal of Science and Technology 2016; 10(3):304-12.

Keeley JE, Bond WJ. Mast flowering and semelparity in bamboos: The bamboo fire cycle hypothesis. The American Naturalist 1999;154(3):383-91.

Khamyong N, Wangpakapattanawong P, Chairuangsri S, Inta A, Tiansawat P. Tree species composition and height-diameter allomery of three forest types in northern Thailand. Chiang Mai University Journal Of Natural Sciences 2018;17(4):289-306.

Klemick H. Shifting cultivation, forest fallow, and externalities in ecosystem services: Evidence from the Eastern Amazon. Journal of Environmental Economics and Management 2011;61(1):95-106.

Krebs CJ. Ecology: The Experimental Analysis of Distribution and Abundance. New York, USA: Harper Collins Publishers; 1994.

Kutintara U, Marod D, Takahashi M, Nakashizuka T. Growth and dynamics of bamboos in a tropical seasonal forest. In: The International Workshop on the Changes of Tropical Forest Ecosystems by El Niño and Others. Bangkok, Thailand: National Research Council; 1995.

Lacerda AEB, Kellermann B. What is the long-term effect of bamboo dominance on adult trees in the Araucaria Forest? A comparative analysis between two successional stages in southern Brazil. Diversity 2019;11(9):Article No. 165.

Larpkern P, Moe SR, Totland Ø. Bamboo dominance reduces tree regeneration in a disturbed tropical forest. Oecologia 2011; 165:161-8.

Laurance WF. Have we overstated the tropical biodiversity crisis? Trends in Ecology and Evolution 2007;22(2):65-70.

Lebrija-Trejos E, Pérez-García EA, Meave JA, Poorter L, Bongers F. Environmental changes during secondary succession in a tropical dry forest in Mexico. Journal of Tropical Ecology 2011;27(5):477-89.

Leishangthem D, Singh MR. Tree diversity, distribution and population structure of a Riparian Forest from certain zones along the Dikhu River in Nagaland, India. Journal of Forest and Environmental Science 2018;34(1):31-45.

Lepore M, Arellano G, Condit R, Davies S, Detto M, Gonzales-Akre E, et al. Fgeo: Analyze forest diversity and dynamics [Internet]. 2019 [cited 2021 May 7]. Available from: https://CRAN.R-project.org/package=fgeo.

Lewis SL, Edwards DP, Galbraith D. Increasing human dominance of tropical forests. Science 2015;349(6250):827-32.

Mabry CM, Fraterrigo JM. Species traits as generalized predictors of forest community response to human disturbance. Forest Ecology and Management 2009;257(2):723-30.

Marod D. Secondary Successional Pattern in Mixed Deciduous Forest of Mae Klong Watershed Research Station Changwat Kanchanavuri [dissertation]. Bangkok, Kasetsart University; 1995 (in Thai).

Marod D, Duengkae P, Sangkaew S, Racharak P, Suksavate W, Uthairatsamee S, et al. Population structure and spatial distribution of tree species in lower Montane Forest, Doi Suthep-Pui National Park, Northern Thailand. Environment and Natural Resources Journal 2022;20(6):644-63.

Marod D, Hermhuk S, Sungkaew S, Thinkampheang S, Kamyo T, Nuipakdee W. Species composition and spatial distribution of dominant trees in the forest ecotone of a mountain ecosystem, northern Thailand. Environment and Natural Resources Journal 2019;17(3):40-9.

Marod D, Kutintara U. Forest Ecology. Bangkok: Department of Forest Biology, Faculty of Forestry; 2009 (in Thai).

Marod D, Kutintara U, Yarwudhi C, Tanaka H, Nakashisuka T. Structural dynamics of a natural mixed deciduous forest in western Thailand. Journal of Vegetation Science 1999; 10(6):777-86.

Marod D, Kutintara U, Tanaka H, Nakashizuka T. The effects of drought and fire on seed and seedling dynamics in a tropical seasonal forest in Thailand. Plant Ecology 2002;161:41-57.

Marod D, Kutintara U, Tanaka H, Nakashizuka T. Effects of drought and fire on seedling survival and growth under contrasting light conditions in a seasonal tropical forest. Journal of Vegetation Science 2004;15(5):691-700.

Marod D, Lamthai A, Duengkae P, Pattanavibool A. Vegetation structure and floristic composition along the edge of Montane Forest and agricultural land in Um Phang Wildlife Santuary, Western Thailand. Agriculture and Natural Resources 2012; 46(2):162-80.

Matsuo T, Martínez‐Ramos M, Bongers F, van der Sande MT, Poorter L. Forest structure drives changes in light heterogeneity during tropical secondary forest succession. Journal of Ecology 2021;109(8):2871-84.

Miles L, Newton AC, DeFries RS, Ravilious C, May I, Blyth S, et al. A global overview of the conservation status of tropical dry forest. Journal of Biogeography 2006;33(3):491-505.

Mohandass D, Hughes AC, Mackay B, Davidar P, Chhabra T. Floristic species composition and structure of a mid-elevation tropical montane evergreen forests (sholas) of the western ghats, southern India. Tropical Ecology 2016;57(3):533-43.

Mondoni A, Orsenigo S, Abeli T, Rossi G, Brancaleoni L, Corli A, et al. Plant regeneration above the species elevational leading edge: Trade-off between seedling recruitment and plant production. Frontiers in Ecology and Evolution 2020;8:Article No. 572878.

Phumphuang W, Marod D, Sungkaew S, Thinkampaeng S. Forest dynamics and tree distribution patterns in dry evergreen forest, northeastern, Thailand. Environment and Natural Resources Journal 2018;16(2):58-67.

Poorter L, Rozendaal DM, Bongers F, Almeida DJS, Álvarez FS, Andrade JL, et al. Functional recovery of secondary tropical forests. Proceedings of the National Academy of Sciences 2021;118(49):e2003405118.

Pothasin P, Compton SG, Wangpakapattanawong P. Riparian Ficus tree communities: The distribution and abundance of riparian fig trees in Northern Thailand. PLoS ONE 2014;9(10):e108945.

Quesada M, Stoner KE. Threats to the conservation of the tropical dry forest in Costa Rica. In: Frankie GW, Mata A, Vinson SB, editors. Biodiversity Conservation in Costa Rica: Learning the Lessons in a Seasonal Dry Forest. Berkeley: University of California Press; 2004. p. 266-80.

R Core Team. A language and environment for statistical computing, R Foundation for Statistical Computing [Internet]. 2017 [cited 2020 Jun 15]. Available from: http://www.R-project.org/.

Rong L, Duan X, Feng D, Zhang G. Soil moisture variation in a farmed dry-hot valley catchment evaluated by a redundancy analysis approach. Water 2017;9(2):Article No. 92.

Rother DC, Pizo MA, Siqueira T, Rodrigues RR, Jordano P. Community-wide spatial and temporal discordances of seed-seedling shadows in a tropical rainforest. PLoS ONE 2015;10(4):e0123346.

Rueangket A, Duengkae P, Thinkhampang S, Marod D. Utilization of fruit by frugivores in lower montane forest at Doi Suthep-Pui National Park, Chiang Mai Province. Agriculture and Natural Resources 2019;53(5):457-64.

Sanchez-Azofeifa GA, Quesada M, Calvo J, Rodriguez JP, Nassar J, Garvin T, et al. Research priorities for tropical secondary dry forests. Biotropica 2005;37:477-85.

Sangsupan HA, Hibbs DE, Withrow-Robinson BA, Elliott S. Effect of microsite light on survival and growth of understory natural regeneration during restoration of seasonally dry tropical forest in upland northern Thailand. Forest Ecology and Management 2021;489:Article No. 119061.

Sann B, Kanzaki M, Ohta S. Vegetation patterns and species-filtering effects of soil in secondary succession in a tropical dry forest in central Myanmar. Journal of Tropical Ecology 2016;32(2):116-24.

Sasunti A, Asanog L. Tree Species Regeneration in Forest Restoration Area by Economic Tree at Nan Watershed, Nan Province [dissertation]. Chiang Mai, Maejo University; 2021.

Scheper AC, Verweij PA, Kuijk VM. Post-fire forest restoration in the humid tropics: A synthesis of available strategies and knowledge gaps for effective restoration. Science of the Total Environment 2021;771:Article No. 144647.

Sellan G, Thompson J, Majalap N, Brearley FQ. Soil characteristics influence species composition and forest structure differentially among tree size classes in a Bornean heath forest. Plant and Soil 2019;438(1):173-85.

Shannon CE, Weaver W. The Mathematical Theory of Communication. Illinois, United States of America: University of Illinois Press; 1949.

Shumi G, Dorresteijn I, Schultner J, Hylander K, Senbeta F, Hanspach J, et al. Woody plant use and management in relation to property rights: A social-ecological case study from southwestern Ethiopia. Ecosystems and People 2019; 15(1):303-16.

Smitinand T. Thai Plant Names. Bangkok, Thailand: Department of National Parks, Wildlife and Plant Conservation; 2014 (in Thai).

Soil Science Division Staff. Soil Survey Manual: United States Department of Agriculture Handbook No. 18. USA: United States Department of Agriculture; 2017.

Staelens J, Nachtergale L, Schrijver DA, Vanhellemont M, Wuyts K, Verheyen K. Spatio-temporal litterfall dynamics in a 60-year-old mixed deciduous forest. Annals of Forest Science 2011;68:89-98.

Suksawang S. Site Overview: Thong Pha Phoom Study Site. Bangkok, Thailand: Royal Forest Department; 1993.

Sullivan MJ, Talbot J, Lewis SL, Phillips OL, Qie L, Begne SK, et al. Diversity and carbon storage across the tropical forest biome. Scientific Reports 2017;7(1):Article No. 39102.

Swinfield T, Afriandi R, Antoni F, Harrison RD. Accelerating tropical forest restoration through the selective removal of pioneer species. Forest Ecology and Management 2016; 381:209-16.

Takahashi M, Kutintara U, Eaidthong W, Kobayashi S. Changes of the vegetation pattern in different successional stages. Proceedings of the International Workshop on the Changes of Tropical Forest Ecosystems by El Niño and Others; 1995 Feb 7-10; Kanchanaburi: Thailand; 1995.

Takahashi M, Marod D, Panuthai S, Hirai K. Carbon cycling in teak plantations in comparison with seasonally dry tropical forests in Thailand. In: Blanco JA, Lo YH, editors. Forest Ecosystems More Than Just Trees. Rijeka: InTech; 2012. p. 209-30.

Thein HM, Kanzaki M, Fukushima M. Structure and composition of a teak-bearing forest under the Myanmar Selection System: impacts of logging and bamboo flowering. Southeast Asian Studies 2007;45(3):303-16.

Van Hall RL, Cammeraat LH, Keesstra SD, Zorn M. Impact of secondary vegetation succession on soil quality in a humid Mediterranean landscape. Catena 2017;149:836-43.

Wang J, Wang H, Cao Y, Bai Z, Qin Q. Effects of soil and topographic factors on vegetation restoration in opencast coal mine dumps located in a loess area. Scientific Reports 2016;6(1):1-11.

Wang XY, Ling HB, Xu HL, De Pan C, Yuan KY. Relationships between plant communities and environmental factors in an extremely arid area: A case study in China. Polish Journal of Environmental Studies 2019;28(1):359-70.

Wright SJ. Tropical forests in a changing environment. Trends in Ecology and Evolution 2005;20(10):553-60.

Yarwudhi C, Tanaka N, Kobayashi S, Marod D, Kutintara U, Tabaka H, et al. Regeneration dynamics of tree after the simultaneous flowering and death of undergrowing bamboo in a mixed deciduous forest, western Thailand. Proceedings of the International Workshop on the Responses of Tropical Forest Ecosystem to Long Term Cyclic Climate Changes; 2000 Jan 24-27; Kanchanaburi: Thailand; 2000.

Zhang ZH, Hu G, Ni J. Effects of topographical and edaphic factors on the distribution of plant communities in two subtropical karst forests, Southwestern China. Journal of Mountain Science 2013;10(1):95-104.

Zhao H, Wang QR, Fan W, Song GH. The relationship between secondary forest and environmental factors in the southern Taihang Mountains. Scientific Reports 2017;7(1):Article No. 16431.