Jiang, M. and Crous, K.Y. and Carrillo, Y. and Macdonald, C.A. and Anderson, I.C. and Boer, M.M. and Farrell, M. and Gherlenda, A.N. and Castañeda-Gómez, L. and Hasegawa, S. and Jarosch, K. and Milham, P.J. and Ochoa-Hueso, R. and Pathare, V. and Pihlblad, J. and Piñeiro, J. and Powell, J.R. and Reich, P.B. and Riegler, M. and Zaehle, Sonke and Smith, B. and Medlyn, B.E. and Ellsworth, D.S. (2024) Microbial competition for phosphorus limits the CO2 response of a mature forest. Nature, 630. pp. 660-665. ISSN 0028-0836
Full text not available from this repository.Abstract
The capacity for terrestrial ecosystems to sequester additional carbon (C) with rising CO2 concentrations depends on soil nutrient availability1,2. Previous evidence suggested that mature forests growing on phosphorus (P)-deprived soils had limited capacity to sequester extra biomass under elevated CO2 (refs. 3,4,5,6), but uncertainty about ecosystem P cycling and its CO2 response represents a crucial bottleneck for mechanistic prediction of the land C sink under climate change7. Here, by compiling the first comprehensive P budget for a P-limited mature forest exposed to elevated CO2, we show a high likelihood that P captured by soil microorganisms constrains ecosystem P recycling and availability for plant uptake. Trees used P efficiently, but microbial pre-emption of mineralized soil P seemed to limit the capacity of trees for increased P uptake and assimilation under elevated CO2 and, therefore, their capacity to sequester extra C. Plant strategies to stimulate microbial P cycling and plant P uptake, such as increasing rhizosphere C release to soil, will probably be necessary for P-limited forests to increase C capture into new biomass. Our results identify the key mechanisms by which P availability limits CO2 fertilization of tree growth and will guide the development of Earth system models to predict future long-term C storage.