Temporal variability in the thermal requirements for vegetation phenology on the Tibetan plateau and its implications for carbon dynamics

Zhenong Jin, Qianlai Zhuang (), Jeffrey S. Dukes, Jin-Sheng He, Andrei P. Sokolov, Min Chen, Tonglin Zhang and Tianxiang Luo
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Zhenong Jin: Purdue University
Qianlai Zhuang: Purdue University
Jeffrey S. Dukes: Purdue University
Jin-Sheng He: Chinese Academy of Sciences
Andrei P. Sokolov: Massachusetts Institute of Technology
Min Chen: Purdue University
Tonglin Zhang: Purdue University
Tianxiang Luo: Chinese Academy of Sciences

Climatic Change, 2016, vol. 138, issue 3, No 18, 617-632

Abstract: Abstract Static thermal requirements (T req ) are widely used to model the timing of phenology, yet may significantly bias phenological projections under future warming conditions, since recent studies argue that climate warming will increase T req for triggering vegetation phenology. This study investigates the temporal trend and inter-annual variation of T req derived from satellite-based spring and autumn phenology for the alpine and temperate vegetation on the Tibetan Plateau from 1982 to 2011. While we detected persistent warming in both spring and autumn across this time period, we did not find a corresponding long-term increase in T req for most of the study area. Instead, we found a substantial interannual variability of T req that could be largely explained by interannual variations in other climatic factors. Specifically, the number of chilling days and fall temperature were robust variables for predicting the dynamics of T req for spring onset and autumn senescence, respectively. Phenology models incorporating a dynamic T req algorithm performed slightly better than those with static T req values in reproducing phenology derived from SPOT-VGT NDVI data. To assess the degree to which T req variation affects large-scale phenology and carbon cycling projections, we compared the output from versions of the Terrestrial Ecosystem Model that incorporated static and dynamic T req values in their phenology algorithms. Under two contrasting future climate scenarios, the dynamic T req setting reduced the projected growing season length by up to 1–3 weeks by the late twenty-first century, leading to a maximum reduction of 8.9 % in annual net primary production and ~15 % in cumulative net ecosystem production for this region. Our study reveals that temporal dynamics of T req meaningfully affect the carbon dynamics on the Tibetan Plateau, and should thus be considered in future ecosystem carbon modeling.

Date: 2016
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DOI: 10.1007/s10584-016-1736-8

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