Norby, R.J. and Loader, N.J. and Mayoral, C. and Ullah, S. and Curioni, G. and Smith, A.R. and Reay, M.K. and van Wijngaarden, K. and Amjad, M.S. and Brettle, D. and Crockatt, M.E. and Denny, G. and Grzesik, R.T. and Hamilton, R.L. and Hart, K.M. and Hartley, I.P. and Jones, A.G. and Kourmouli, A. and Larsen, J.R. and Shi, Z. and Thomas, R.M. and MacKenzie, A.R. (2024) Enhanced woody biomass production in a mature temperate forest under elevated CO2. Nature Climate Change, 14 (9). pp. 983-988. ISSN 1758-678X
Full text not available from this repository.Abstract
Enhanced CO2 assimilation by forests as atmospheric CO2 concentration rises could slow the rate of CO2 increase if the assimilated carbon is allocated to long-lived biomass. Experiments in young tree plantations support a CO2 fertilization effect as atmospheric CO2 continues to increase. Uncertainty exists, however, as to whether older, more mature forests retain the capacity to respond to elevated CO2. Here, aided by tree-ring analysis and canopy laser scanning, we show that a 180-year-old Quercus robur L. woodland in central England increased the production of woody biomass when exposed to free-air CO2 enrichment (FACE) for 7 years. Further, elevated CO2 increased exudation of carbon from fine roots into the soil with likely effects on nutrient cycles. The increase in tree growth and allocation to long-lived woody biomass demonstrated here substantiates the major role for mature temperate forests in climate change mitigation.