Temperature and vegetation seasonality diminishment over northern lands
Xu, L.; Myneni, R.B.; Chapin III, F.S.; Callaghan, T.V.; Pinzon, J.E.; Tucker, Compton J.; Zhu, Z.; Bi, J.; Ciais, P.; Tømmervik, Hans; Euskirchen, E.S.; Forbes, B. C.; Piao, S.L.; Anderson, B.T.; Ganguly, S.; Nemani, R.R.; Goetz, S.J.; Beck, P.S.A.; Bunn, A.G.; Cao, C.; Stroeve, J.C.
Journal article, Peer reviewed
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Date
2013Metadata
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Abstract
Global temperature is increasing, especially over Northern lands (>50 N), owing to positive feedbacks. As this increase is most pronounced in winter, temperature seasonality (ST)—conventionally defined as the difference between summer and winter temperatures—is diminishing over time, a phenomenon that is analogous to its equatorward decline at an annual scale. The initiation, termination and performance of vegetation photosynthetic activity are tied to threshold temperatures.
Trends in the timing of these thresholds andcumulative temperatures above them may alter vegetation
productivity, or modify vegetation seasonality (SV), over time. The relationship between ST and SV is critically examined here with newly improved ground and satellite data sets. The observed diminishment of ST and SV is equivalent to 4 and 7 (5 and 6 ) latitudinal shift equatorward during the past 30 years in the Arctic (boreal) region. Analysis of simulations from 17 state-of-the-art climate models4 indicates
an additional ST diminishment equivalent to a 20 equatorward shift could occur this century. How SV will change in response to such large projected ST declines and the impact this will have on ecosystem services5 are not well understood. Hence the need for continued monitoring6 of northern lands as
their seasonal temperature profiles evolve to resemble those further south.