Responses of tree growth and intrinsic water-use efficiency of Robinia pseudoacacia to climate factors

doi:10.13287/j.1001-9332.202310.011

Abstract

Abstract: We investigated tree growth in Robinia pseudoacacia plantations at Ansai in Shaanxi Province and at Ji-xian in Shanxi Province by comparing the tree-ring width, basal area increase (BAI), δ¹³C value, intrinsic water-use efficiency (iWUE), and stomatal regulation. We quantified the responses of tree growth and iWUE to climatic factors at each site. The tree-ring width at Ansai and Jixian decreased with stand age, whereas the BAI at Ansai increased, and that at Jixian decreased after the BAI peaked. The δ¹³C value and iWUE of trees at Jixian were higher than those at Ansai. The iWUE of trees at both sites was similar to the constant intercellular CO₂ concentration/atmospheric CO₂ concentration (C_i/C_a) scenario, indicating that the C_i of trees was elevated with increasing C_a, while the stomata remained open. The BAI at Ansai was significantly positively correlated with highest temperature in May, relative humidity in June, precipitation in August, relative humidity in September, and standardized precipitation evapotranspiration index (SPEI) in September and October of current year, but negatively correlated with temperature in June. The BAI at Jixian was significantly positively correlated with SPEI in June and July, and lowest temperature in October of current year. The iWUE of trees at Ansai was significantly positively correlated with relative humidity and precipitation in June of the current year, but negatively correlated with minimum temperature in May, relative humidity in June, and temperature and maximum temperature in July of current year. A significant positive correlation between iWUE of trees at Jixian and lowest temperature in June of current year was detected. At the annual scale, the BAI of trees at Ansai was positively correlated with precipitation and SPEI, but no significant relationship was observed for trees at Jixian. However, the iWUE of trees at both sites was significantly affected by precipitation. Path analysis showed that SPEI and minimum temperature had a direct effect on BAI and iWUE of trees at Ansai, whereas precipitation and average temperature indirectly affected BAI and iWUE through SPEI. The highest temperature had a direct effect on tree growth at Jixian, whereas precipitation, minimum temperature, and average temperature had direct effects on iWUE. These results suggested that SPEI was the main climatic factor that affected the growth of R. pseudoacacia, while C_i was an important physiological factor. Our results could provide reference for the protection and management of R. pseudoacacia plantations under climate change.

Key words: stable isotope, water use efficiency, climate response, Robinia pseudoacacia, stomatal regulation

HU Xiaochuang, GAO Wanting, SUN Shoujia, ZHANG Jinsong, MENG Ping, CAI Jinfeng. Responses of tree growth and intrinsic water-use efficiency of Robinia pseudoacacia to climate factors[J]. Chinese Journal of Applied Ecology, 2023, 34(10): 2610-2618.

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