Divergent apparent temperature sensitivity of terrestrial ecosystem respiration

0431492 - ÚVGZ 2015 RIV GB eng J - Journal Article
Song, B. - Niu, S. - Luo, R. - Chen, J. - Yu, G. - Olejnik, Janusz - Wohlfahrt, G. - Kiely, G. - Noormels, A. - Montagnani, L. - Cescatti, A. - Magliulo, V. - Law, B. E. - Lund, M. - Varlagin, A. - Raschi, A. - Peichl, M. - Nilsson, M. - Merbold, L.
Divergent apparent temperature sensitivity of terrestrial ecosystem respiration.
Journal of Plant Ecology. Roč. 7, č. 5 (2014), s. 419-428. ISSN 1752-9921. E-ISSN 1752-993X
Institutional support: RVO:67179843
Keywords : activation energy * ecosystem respiration * index of water availability * gross primary productivity
Subject RIV: EH - Ecology, Behaviour
Impact factor: 2.646, year: 2014

Aims Recent studies revealed convergent temperature sensitivity of ecosystem respiration (R e) within aquatic ecosystems and between terrestrial and aquatic ecosystems. We do not know yet whether various terrestrial ecosystems have consistent or divergent temperature sensitivity. Here, we synthesized 163 eddy covariance flux sites across the world and examined the global variation of the apparent activation energy (Ea), which characterizes the apparent temperature sensitivity of R e, and its interannual variability (IAV) as well as their controlling factors. Methods We used carbon fluxes and meteorological data across FLUXNET sites to calculate mean annual temperature, temperature range, precipitation, global radiation, potential radiation, gross primary productivity and R e by averaging the daily values over the years in each site. Furthermore, we analyzed the sites with >8 years data to examine the IAV of Ea and calculated the standard deviation of Ea across years at each site to characterize IAV. Important Findings The results showed a widely global variation of Ea, with significantly lower values in the tropical and subtropical areas than in temperate and boreal areas, and significantly higher values in grasslands and wetlands than that in deciduous broadleaf forests and evergreen forests. Globally, spatial variations of Ea were explained by changes in temperature and an index of water availability with differing contribution of each explaining variable among climate zones and biomes. IAV and the corresponding coefficient of variation of Ea decreased with increasing latitude, but increased with radiation and corresponding mean annual temperature. The revealed patterns in the spatial and temporal variations of Ea and its controlling factors indicate divergent temperature sensitivity of R e, which could help to improve our predictive understanding of R e in response to climate change.
Permanent Link: http://hdl.handle.net/11104/0236108