Declining tree growth rates despite increasing water-use efficiency under elevated CO(2) reveals a possible global overestimation of CO(2) fertilization effect

Though rising atmospheric CO(2) concentrations (C(a)) harm the environment and society, they may also raise photosynthetic rates and enhance intrinsic water-use efficiency (iWUE). Numerous short-term studies have investigated tree growth under elevated CO(2) (eCO(2)) conditions, but no long-duration study has investigated eCO(2) impacts on tree growth and iWUE under natural conditions. Utilizing a new dendrochronological experimental design in a heavily-touristed nature preserve in Southwest China (Jiuzhaigou National Nature Reserve), we compared tree growth (e.g., basal area increment) and iWUE in two biophysically and environmentally similar valleys with contrasting anthropogenic activities. Trees in the control valley with ambient CO(2) benefited from increasing C(a), possibly due to the CO(2) fertilization effect and optimal environmental conditions. However, trees in the treatment valley with intensive tourism experienced comparatively higher localized eCO(2) and growth rate declines. While iWUE increased (1959–2017) in the control (25.3%) and treatment sites (47.8%), declining tree growth rates in the treatment site was likely because comparatively extreme CO(2) exposure levels encouraged stomatal closures. As the first long-term study investigating eCO(2) impacts on tree growth and iWUE under natural conditions, we demonstrate that increased forest iWUE is unlikely to overcome negative drought stress and rising temperature impacts. Thus, forest potential for mitigating eCO(2) and global climate change is likely overestimated, particularly under dry temperate conditions.