Interspecific association patterns of woody species in an evergreen broadleaved forest of Con Dao National Park, Vietnam


Authors

  • Nguyen Hong Hai Vietnam National University of Forestry
  • Vu Manh Southern Branch of Joint Vietnam - Russia Tropical Science and Technology Research Center
  • Pham Thanh Trang Vietnam National University of Forestry
  • Nguyen Van Quy Southern Branch of Joint Vietnam - Russia Tropical Science and Technology Research Center
DOI: https://doi.org/10.55250/Jo.vnuf.9.2.2024.022-031

Keywords:

Community organization, Gleason's hypothesis, null models, species interactions, theoretical ecology

Abstract

The interspecific associations among tree species in natural forest stands help to reveal mechanisms for maintaining species diversity and provide theoretical foundations for vegetation restoration and regeneration. This study focused on woody species within a 4-ha study plot established in an evergreen broadleaved forest in Con Dao National Park, Vietnam. We analyzed the interspecific associations among sixty-four recorded woody species in the study plot based on their presence and absence in subplots at two sampling scales: 10 m × 10 m and 20 m × 20 m. The results indicated that most of the 3,969 pairs of the sixty-four species exhibited independent associations, confirming an individualistic hypothesis proposed by Gleason. Furthermore, species interactions of common species were stronger than those of rare ones, indicating that species abundance influenced interspecific associations, and this result acknowledges the presence of random processes in driving species coexistence. A comparison of observed communities and random communities based on null models revealed that deterministic processes play a dominant role in governing species co-occurrence within the tree communities in the study area. Our study provides insights into the complex dynamics of species interactions within forest ecosystems, contributing to our understanding of biodiversity maintenance and offering valuable guidance for conservation and restoration efforts.

References

. Maihaiti M. & Zhang W. J. (2014). A mini review on theories and measures of interspecific associations. Selforganizology. 1(3-4): 206-210.

. Wiegand T., Gunatilleke S. & Gunatilleke N. (2007). Species associations in a heterogeneous Sri Lankan dipterocarp forest. The American Naturalist. 170(4): E77-E95.

. Ofomata V. C., Overholt W. A., Van Huis A., Egwuatu R. I. & Ngi‐Song A. J. (1999). Niche overlap and interspecific association between Chilo partellus and Chilo orichalcociliellus on the Kenya coast. Entomologia Experimentalis et Applicata. 93(2): 141-148.

. Cornell H. V. & Lawton J. H. (1992). Species interactions, local and regional processes, and limits to the richness of ecological communities: a theoretical perspective. Journal of Animal ecology. 1-12.

. Pocheville A. (2015). The ecological niche: history and recent controversies. Handbook of evolutionary thinking in the sciences. 74(1): 547-586.

. D'Amen M., Mod H. K., Gotelli N. J. & Guisan A. (2018). Disentangling biotic interactions, environmental filters, and dispersal limitation as drivers of species co‐occurrence. Ecography. 41(8): 1233-1244.

. Trisos C. H., Petchey O. L. & Tobias J. A. (2014). Unraveling the interplay of community assembly processes acting on multiple niche axes across spatial scales. The American Naturalist. 184(5): 593-608.

. Mutshinda C. M., O'Hara R. B. & Woiwod I. P. (2009). What drives community dynamics? Proceedings of the Royal Society B: Biological Sciences. 276(1669): 2923-2929.

. Gravel D., PoisoT T. & Desjardins-Proulx P. (2014). Using neutral theory to reveal the contribution of meta-community processes to assembly in complex landscapes. Journal of Limnology. 7: s5433.

. Roy M., Pascual M. & Levin S. A. (2004). Competitive coexistence in a dynamic landscape. Theoretical Population Biology. 66(4): 341-353.

. Caruso T., Chan Y., Lacap D. C., Lau M. C. Y., McKay C. P. & Pointing S. B. (2011). Stochastic and deterministic processes interact in the assembly of desert microbial communities on a global scale. The ISME journal. 5(9): 1406-1413.

. Cordero R. D. & Jackson D. A. (2019), Species pair associations, null models, and tests of mechanisms structuring ecological communities. Ecosphere 10(7): e02797.

. Gleason H. A. (1926). The individualistic concept of the plant association. Bulletin of the Torrey botanical club. 12(1): 7-26.

. Clements F. E. (1916). Plant succession: an analysis of the development of vegetation. ed. Carnegie institution of Washington.

. Eliot C. (2007). Method and metaphysics in Clements’s and Gleason’s ecological explanations. Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences. 38(1): 85-109.

. Liu X. Y., He D., Tian W. B., Song Y. J., Yin F., Xu M. S., Cheng J. Y. & Yan E. R. (2017). Patterns of species associations in woody plants in forest communities of Putuoshan Island, Zhejiang, China. Chinese Journal of Plant Ecology. 41(12): 1219.

. Nguyen Van Quy, Nguyen Hong Hai, Nguyen Thanh Tuan, Nguyen Van Hop, Pham Van Dinh & Pham Thanh Ha (2023). Coexistence mechanisms of woody plant species in a natural forest in Dong Nai Culture and Nature Reserve. Journal of Forestry Science and Technology. 2: 44-53.

DOI: 10.55250/jo.vnuf.2023.2.044-053

. Nguyen Van Quy, Nguyen Van Hop, Pham Mai Phuong & Nguyen Hong Hai (2023). Coexistence mechanisms of tree species in an evergreen forest on Con Dao islands, Vietnam. Biology Bulletin. 50(16): 233-249.

. Tran Hop (2002). Timber resources in Vietnam. ed. Agricultural Publishing House. Hanoi, Vietnam.

. Pham Hoang Ho (1999). An Illustrated Flora of Vietnam. ed. Tre Publishing House. Hanoi, Vietnam.

. Arbainsyah, de Iongh H. H., Kustiawan W. & De Snoo G. R. (2014). Structure, composition and diversity of plant communities in FSC-certified, selectively logged forests of different ages compared to primary rain forest. Biodiversity and conservation. 23: 2445-2472.

. Thai Van Trung (1978). The vegetation cover in Vietnam. ed. Science and Technology Publishing House. Hanoi, Vietnam.

. Schluter D. (1984). A variance test for detecting species associations, with some example applications. Ecology. 65(3): 998-1005.

. Hurlbert S. H. (1969). A coefficient of interspecific assciation. Ecology. 50(1): 1-9.

. Yarranton G. A. (1966). A plotless method of sampling vegetation. The Journal of Ecology. 49(3): 229-237.

. Lawlor L. R. (1980). Structure and stability in natural and randomly constructed competitive communities. The American Naturalist. 116(3). 394-408.

. Stone L. & Roberts A. (1990). The checkerboard score and species distributions. Oecologia. 85(7): 74-79.

. R Core Team (2015). R: a language and environment for statistical computing. ed. R Foundation for Statistical Computing. Vienna.

. Lieberman M. & Lieberman D. (2007). Nearest‐neighbor tree species combinations in tropical forest: the role of chance, and some consequences of high diversity. Oikos. 116(3): 377-386.

. He D. (2016). Plant functional trait variation and community assembly: a case study in a subtropical evergreen forest. ed. Sun Yat-sen University. Guangzhou, China.

. Shmida A. & Ellner S. (1984). Coexistence of plant species with similar niches. Vegetatio. 58(2): 29-55.

. Mohd M. H., Murray R., Plank M. J. & Godsoe W. (2016). Effects of dispersal and stochasticity on the presence–absence of multiple species. Ecological Modelling. 342: 49-59.

. Mittelbach G. G. & McGill B. J. (2019). Community ecology. ed. Oxford University Press.

. E. S. R. & Chesson P. (2004). How the spatial scales of dispersal, competition, and environmental heterogeneity interact to affect coexistence. The American Naturalist. 164(5): 633-650.

. Bulleri F., Bruno J. F., Silliman B. R. & Stachowicz J. J. (2016). Facilitation and the niche: implications for coexistence, range shifts and ecosystem functioning. Functional Ecology. 30(1). 70-78.

. Brown J. H. (1984). On the relationship between abundance and distribution of species. The american naturalist. 124(2): 255-279.

. Zhou X. Y., Wang B. S., Li M. G. & Zang Q. J. (2000). An analysis of interspecific associations in secondary succession forest communities in Heishiding Natural Reserve, Guangdong province. Chinese Journal of Plant Ecology. 24(3): 332.

. Jin S. S., Zhang Y. Y., Zhou M. L., Dong X. M., Chang C. H., Wang T. & Yan D. F. (2022). Interspecific association and community stability of tree species in natural secondary forests at different altitude gradients in the southern Taihang Mountains. Forests. 13(3): 373.

. Cadenasso M. L., Pickett S. T., Weathers K. C. & Jones C. G. (2003). A framework for a theory of ecological boundaries. BioScience. 53(8): 750-758.

. Tilman D., Kareiva P., Holmes E. & Lewis M. (1994). Space: the final frontier for ecological theory. Ecology. 75(1): 1.

Metrics

Metrics Loading ...

Downloads

Abstract View: 30
PDF Downloaded: 23

Published

12-11-2024

How to Cite

Hong Hai, N., Manh, V., Thanh Trang, P., & Van Quy, N. (2024). Interspecific association patterns of woody species in an evergreen broadleaved forest of Con Dao National Park, Vietnam. Journal of Forestry Science and Technology, 9(2), 022–031. https://doi.org/10.55250/Jo.vnuf.9.2.2024.022-031

Issue

Vol. 9 No. 2 (2024)

Section

Silviculture and Forest Inventory-Planning