Responses of radial growth to climate change in Pinus massoniana at different altitudes and slopes.

doi:10.13287/j.1001-9332.201907.011

Abstract

Abstract: With dendrochronology method, standard and residual chronologies of Pinus massoniana were established at low altitude (260 m), middle altitude (460 m), high altitude (690 m), sunny slope (270 m), and shady slope (265 m). Relationships between the tree-ring width and the climatic factors were quantified using correlation analysis and redundancy analysis (RDA). The optimal multiple regression models for the radial growth of P. massoniana and the climatic factors were established. We analyzed the change rule of radial growth and its relationship with the climatic factors along with the altitude and slope. The results showed that the radial growth of P. massoniana was significantly affected by precipitation and temperature across the altitude gradient and the slope level, respectively. Among the 120 climatic variables, precipitation in December of last year and the extreme minimum temperature in February of current year had the most significant negative effects on the radial growth at different altitudes and slopes, respectively. This study quantitatively described the impacts of climate change on the radial growth of P. massoniana in the subtropical region, and provided a scientific basis for the planting and management of P. massoniana forest in Jiangle Country under the climate warming background.

Key words: slope aspect, tree-ring, altitude gradient, Pinus massoniana, climate change.

QIAO Jing-jing, WANG Tong, PAN Lei, SUN Yu-jun. Responses of radial growth to climate change in Pinus massoniana at different altitudes and slopes.[J]. Chinese Journal of Applied Ecology, 2019, 30(7): 2231-2240.

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