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Relative importance of biotic, abiotic and stand age factors in influencing ecosystem multifunctionality across forest stand types in South Korea

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Publicado en:Frontiers in Forests and Global Change vol. 8 (Oct 2025), p. 1675167-1675179
Autor principal: Lee, Min-Ki
Otros Autores: Chun, Jung-Hwa, Lee, Chang-Bae
Publicado:
Frontiers Media SA
Materias:
South Korea
Forest management
Stand structure
Age factors
Water stress
Sustainability management
Ecological succession
Topography
Coniferous forests
Biodiversity
Age
Hydrology
Sustainable ecosystems
Ecological function
Plant species
Forests
Ecosystems
Abiotic factors
Trees
Sustainable forestry
Precipitation
Carbon sequestration
Low frequency
Hypotheses
Ecosystem management
National forests
Plant diversity
Structure-function relationships
Electromagnetic fields
Aridity
Environmental
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Resumen:Introduction: In order to effectively manage ecosystems, it is important to understand how the structure and function of the ecosystem are measured and interpreted, and ecosystem multifunctionality (EMF) is being used as an important indicator for providing sustainable ecosystem functions and managing qualitative stability. The objective of this study is to examine the biotic and abiotic mechanisms underlying the production and regulation of EMF within various forest stand types.Methods: To this end, we assessed the influence of biotic (tree species, functional, and stand structural diversity of trees), abiotic (elevation, aridity index), and stand age (mean age of the five dominant trees per plot) factors on EMF. A total of 2,859 natural forest plots—comprising coniferous, broadleaved, and mixed stands—were analyzed based on data from the 7th National Forest Inventory of South Korea. To determine the major factors influencing EMF, we applied a multi-model inference approach along with piecewise structural equation modeling.Results: Our results suggest that higher plant biodiversity was positively associated with EMF. In addition, older forests exhibit greater stand structural diversity, which in turn enhances the maintenance of EMF. The analysis of abiotic factors revealed that EMF increased with elevation. Furthermore, variables related to plant water stress consistently had negative direct and indirect effects across all forest stand types. Finally, the mechanisms controlling EMF differed among forest stand types.Discussion: These findings suggest that promoting forest succession, maintaining biodiversity, and enhancing stand structural diversity are essential forest management strategies for improving EMF. Furthermore, since the controlling factors of EMF varied among forest stand types, forest-type specific management strategies are required. Lastly, this study provides valuable insights for guiding sustainable forest management that enhances both EMF and specific ecosystem functions, while supporting human well-being.
ISSN:2624-893X
DOI:10.3389/ffgc.2025.1675167
Fuente:Agriculture Science Database