EGU24-1124, updated on 08 Mar 2024
https://doi.org/10.5194/egusphere-egu24-1124
EGU General Assembly 2024
© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Summer aridity decouples growth from carbon assimilation in temperate oaks

Mukund Palat Rao1,2, Arturo Pacheco-Solana2, Johanna E. Jensen3, Rong Li4, Kevin L Griffin2, Neil Pederson5, Luke M McCormack6, Joseph Verfaillie7, Xi Yang4, Dennis Baldocchi7, Laia Andreu-Hayles1,2, Bar Oryan8, Jeremy Hise9, Milagros Rodriguez-Catón10, Alex Turner11, Jan Eitel12, Todd M Scanlon4, Zoe Pierrat13, Josep Penuelas1, and Troy Magney10
Mukund Palat Rao et al.
  • 1CREAF. Barcelona
  • 2Lamont Doherty Earth Observatory
  • 3Pachama
  • 4University of Virginia
  • 5Harvard Forest
  • 6The Morton Arboretum
  • 7UC Berkeley
  • 8Ecole Normale Supérieure
  • 9Hise Scientific
  • 10University of California Davis
  • 11University of Washington
  • 12University of Iowa
  • 13NASA-JPL

Forest biomass resulting from tree radial growth can remain on the landscape over decadal to centennial timescales and plays a critical role in forest carbon cycling. However, visually green vegetation may not be a good proxy for carbon allocation to growth as the phenology and environmental sensitivity of photosynthesis may be different from radial growth. Here we investigate the decoupling between photosynthesis and tree radial growth across intra to interannual timescales for seven North American oak species (Quercus spp.) at four sites (Lamont Sanctuary, NY; Morton Arboretum, IL; Pace Forest, VA; & Tonzi Vaira, CA, USA). Using point dendrometers and wood anatomy, we find that oak trees generally commenced radial growth (cell division and expansion) one month prior to full canopy development and peak carbon assimilation estimated using eddy covariance, satellite and in-situ remote sensing, and leaf-level chlorophyll fluorescence. Further, radial growth was essentially completed by early summer, two to three months prior to the early autumn end of the photosynthetic activity, and before the annual peak in temperature and vapour pressure deficit (VPD) and lowest soil moisture. This suggests that high summer aridity limits carbon allocation to growth more strongly than assimilation. Tree-ring width chronologies for these species across North America further supports that results that earlywood growth depends on prior season climate and assimilated carbon while latewood growth ends by early-summer and responds primarily to current year climate variability. In summary, temporal decoupling between radial growth and photosynthesis and the stronger constraint of summer aridity on growth than photosynthesis appears to be widespread among multiple North American temperate oak species. As summers continue to warm and dry under climate change, this source-sink (or photosynthesis-growth) decoupling needs to be better resolved to constrain forest carbon cycling, as increasing aridity will likely influence the ability of trees to allocate carbon to long-term storage as woody biomass.

How to cite: Rao, M. P., Pacheco-Solana, A., Jensen, J. E., Li, R., Griffin, K. L., Pederson, N., McCormack, L. M., Verfaillie, J., Yang, X., Baldocchi, D., Andreu-Hayles, L., Oryan, B., Hise, J., Rodriguez-Catón, M., Turner, A., Eitel, J., Scanlon, T. M., Pierrat, Z., Penuelas, J., and Magney, T.: Summer aridity decouples growth from carbon assimilation in temperate oaks, EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-1124, https://doi.org/10.5194/egusphere-egu24-1124, 2024.