A study on the method quantifying the spatial structural diversity of forest stands based on 4 neighborhood trees relationships

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ObjectiveThe ecological significance of 4-variate distribution of stand spatial structure parameters was deeply analyzed and a comprehensive evaluation index of stand spatial structure diversity based on the relationship between adjacent trees was constructed to provide a theoretical basis for formulating targeted forest structure adjustment strategies. MethodBased on the concept of biodiversity, taking the structural unit which composed by reference tree and its nearest four adjacent trees as the object, organically integrate the 4-variate distribution of structural parameters of uniform angle index, mingling, neighborhood comparison and crowding, as well as the number of structural unit trees and forest layers, the genetic absolute distance formula and natural logarithm are used to express the evenness and richness of structural unit types, respectively, and the stand spatial structure diversity index was constructed. The validity of the index was verified by using the long-term positioning monitoring sample plot data ResultUsed the stand spatial structure diversity index (FSD) proposed in this study to measure the spatial structure diversity of forest types in different climatic zones or different origins show that the FSD values of Quercus alienavar. acutiserratanatural forest (0.854) and broad-leaved Pinus koraiensisforest (0.852) were almost the same, indicating that the two forest stands have similar spatial structural diversity. The 4-variate distribution types of Platycladus orientalisplantation was higher than other natural forest, however, its spatial structural diversity (FSD = 0.382) was the lowest in the three stand types, mainly due to its lower diversity in both vertical (FSD _v= 0.369) and horizontal (FSD _h= 0.562) structure than the two natural forest stands. The average number of tree species in the structural units was higher in natural forest than in plantation, with 4.23 in Quercus alienavar . acutiserrataforest, 4.09 in Pinus koraiensisforest, and 1.98 in Platycladus orientalisplantation. The number of tree species in a structural unit fully demonstrate species richness of the structural unit. ConclusionThe integration of the three numbers including 4-variate distribution of stand spatial structure parameters, the number of tree species and number of forest layers in structure unit, lays the foundation for constructing a valid spatial structure diversity index for forest stands. The stand spatial structural diversity index (FSD), based on the concept of biodiversity, is not only a feasible quantitative expression of the 4-variate distribution of structural parameters, but also is an appropriate interpretation of the ecological significance of the 4-variate distribution of structural parameters, and a comprehensive scientific evaluation of the spatial structural diversity of the stand. The index is able to measure the difference of stand spatial structure diversity of different stand types.

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