Intra-annual stem radial growth of Qinghai spruce and its environmental drivers in the Qilian Mountains, northwestern China

Tree stem radial growth could be used to estimate forest productivity, which plays a dominant role in the carbon sink of terrestrial ecosystems. However, it is still obscure how intra-annual stem radial growth is regulated by environmental variables. Here, we monitored Qinghai spruce stem radial gro...

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Bibliographic Details
Published in:The Science of the total environment 2024-03, Vol.915, p.170093-170093, Article 170093
Main Authors: Tian, Quanyan, He, Zhibin, Xiao, Shengchun, Peng, Xiaomei, Lin, Pengfei, Zhu, Xi, Feng, Xiangyan
Format: Article
Language:English
Subjects:
Environmental driver
Growing season length
Growth rate
Qilian Mountains
Stem radial changes
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Summary:Tree stem radial growth could be used to estimate forest productivity, which plays a dominant role in the carbon sink of terrestrial ecosystems. However, it is still obscure how intra-annual stem radial growth is regulated by environmental variables. Here, we monitored Qinghai spruce stem radial growth over seven years and analyzed the environmental drivers of the intra-annual stem radial changes in the Qilian Mountains at low (2700 m) and high altitudes (3200 m). We found that stem radial growth initiated when the daily mean minimum air temperature reached 1.6oC, while the cessation of stem growth was unrelated to temperatures and water conditions. Initiations of stem growth at 2700 m were significantly earlier than that at 3200 m. Maximum growth rates were observed before the summer solstice at low altitude, whereas at high altitude, the majority of them occurred after the summer solstice. Most variability in annual stem increment (AI) can be explained by the rate (Rm) than by the duration of stem growth (∆t), and 78.9 % and 69.6 % of the variability in AI were attributable to Rm for the lower and upper site, respectively. Structural equation modeling revealed that precipitation (P) could both directly positively influence stem radial increment (SRI) and indirectly positively influence SRI through influencing relative humidity (RH), but the positive effect of P on SRI was higher at low altitude than at high altitude. Daily minimum air temperature (Tmin) was also the main direct diver of SRI, and the positive effect of Tmin on SRI was higher at high altitude than at low altitude. Considering the trends in climate warming and humidification over the past decades, climate changes would result in earlier initiation of Qinghai spruce stem growth and promote the growth through positive response to increased precipitation in low altitude and through elevated temperature in high altitude, respectively. [Display omitted] •Minimum temperature is the key factor determining the initiation of Picea crassifolia stem radial growth.•The variation of annual stem increment was explained by the growth rate rather than its duration.•Minimum temperature limits stem growth in high-altitudes, but precipitation determintes stem growth in low-altitudes.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.170093