Environmental Drivers of Gross Primary Production and Evapotranspiration at a Robinia pseudoacacia L. Restoration Plantation

Black locust is the second-most-often planted tree worldwide, particularly for restoration plantations, but drought dieback and growth declines are being reported. Currently, we lack information on these ecosystems' water and carbon fluxes, in relation to climatic variability. Here, we employed eddy covariance to determine the gross primary production (GPP) and evapotranspiration (ET) of a black locust post-mining restoration plantation in NW Greece over c. 2.5 years. Additionally, we applied Generalized Additive Models (GAMs) to study the effects of key environmental drivers (vapour pressure deficit-VPD, soil water content-SWC, solar radiation-Rg and enhanced vegetation index-EVI) on GPP and ET during summer months. Both diurnally and seasonally, GPP increased with increasing Rg, SWC and EVI, but was saturated after certain thresholds (Rg: 400 W m(-2), SWC: 25%, EVI: 0.65). In contrast, GPP declined strongly with increasing VPD. Overall, GPP was maintained at a high level, at the cost of ET, which constantly raised with increasing solar radiation and SWC and was not responsive to enhanced VPD, indicating a non-conservative water use. At present, these black locust plantations exhibit favourable productivity and no drought stress, but increasing VPD in the context of climate change may, ultimately, negatively impact these ecosystems.

Automated summary

Black locust is widely planted for restoration plantations, but drought dieback and growth declines are being observed. This study investigated the water and carbon fluxes of a black locust post-mining restoration plantation in Greece with eddy covariance. It found that GPP increased with Rg, SWC, and EVI, but declined with VPD. ET constantly increased with solar radiation and SWC, but was not responsive to enhanced VPD. The results suggest that increasing VPD due to climate change may negatively impact these ecosystems.