Spatial variations in responses of vegetation autumn phenology to climate change on the Tibetan Plateau

Aims Information about changes in the start and end of the vegetation growing season (SOS and EOS) is crucial for assessing ecosystem responses to climate change because of the high sensitivity of both to climate and their extensive influence on ecological processes in temperate and cold regions. climatic warming substantially advanced SOS on the tibetan Plateau from 1982 to 2011. However, it is unclear why EOS showed little delay despite increasing temperature over this period. Methods We used multiple methods to determine EOS from the satelliteobserved normalized-difference vegetation index and investigated the relationships between EOS and its potential drivers on the tibetan Plateau over 1982–2011. Important findings We found a slight but non-significant delay in regionally averaged EOS of 0.7 day decade−1 (P = 0.18) and a widespread but weak delaying trend across the Plateau over this period. the inter-annual variations in regionally averaged EOS were driven mainly by preseason temperature (partial R = 0.62, P < 0.01), and precipitation and insolation showed weak impact on EOS (P > 0.10). Pre-season warming delayed EOS mainly in the eastern half and north-western area of the plateau. In the south-west, EOS was significantly and positively related to SOS, suggesting potentially indirect effects of winter weather conditions on the following autumn’s phenology through regulation of spring phenology. EOS was more strongly related with pre-season temperature in colder and wetter areas, reflecting vegetation adaptation to local climate. Interestingly, preseason temperature had weaker delaying effects on EOS for vegetation with a shorter growing season, for which SOS had a stronger control on inter-annual variations in EOS than for vegetation with a longer growing season. this indicates that shorter-season tibetan Plateau vegetation may have lower plasticity in adjusting the length of its growing season, whenever it begins, and that climate change is more likely to shift the growing season than extend it for that vegetation.

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