Digging into the roots of belowground carbon cycling following seven years of Prairie Heating and CO2 Enrichment (PHACE), Wyoming USA

Authors: NELSON, L - University Of Wyoming; Blumenthal, Dana; WILLIAMS, D - University Of Wyoming; PENDALL, E - University Of Western Australia

Submitted to: Soil Biology and Biochemistry
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 8/27/2017
Publication Date: 9/4/2017
Citation: Nelson, L., Blumenthal, D.M., Williams, D., Pendall, E. 2017. Digging into the roots of belowground carbon cycling following seven years of Prairie Heating and CO2 Enrichment (PHACE), Wyoming USA. Soil Biology and Biochemistry. 115:169-177. https://doi.org/10.1016/j.soilbio.2017.08.022.
DOI: https://doi.org/10.1016/j.soilbio.2017.08.022

Interpretive Summary: Grassland soils are significant carbon (C) sinks as more than half of grassland plant biomass is belowground and roots are the main source of soil C. It is uncertain if grassland soils will continue as C sinks in the future because climate change may affect the relationships among root crown and root biomass, root chemistry and morphology, and root and soil decomposition. To better understand future belowground C cycling in semiarid grasslands we analyzed root crowns and roots of three native species (Blue grama, needleleaf sedge, and western wheatgrass) and mixed-grass prairie communities, following seven years of simulated climate change at the Prairie Heating and CO2 Enrichment (PHACE) experiment in Wyoming, USA. We found root biomass in the sedge increased under elevated CO2, especially when combined with warming. Decomposition rates of roots from warming plots were higher than those from ambient plots for blue grama and western wheatgrass. Root morphology was altered as well: blue grama root diameter increased under warming, and western wheatgrass root length-per-unit-mass and surface area increased under elevated CO2. Together, our results indicate that grass roots may play a critical role in maintaining soil C stocks in grasslands in the future.

Technical Abstract: Grassland soils are significant carbon (C) sinks as more than half of grassland plant biomass is belowground and roots are the main source of soil C. It is uncertain if grassland soils will continue as C sinks in the future because climate change may affect the dynamic, belowground relationships among crown and root biomass, root chemistry and morphology, and root and soil decomposition, all of which influence C sequestration potential. To better understand future belowground C cycling in semiarid grasslands we analyzed three native species (Bouteloua gracilis, Carex eleocharis, and Pascopyrum smithii) and mixed-grass community crown and root biomass, root chemistry, morphology, and decomposability, and soil organic carbon (SOC) priming following seven years of simulated climate change at the Prairie Heating and CO2 Enrichment (PHACE) experiment in Wyoming, USA. We found that individual species and the community respond uniquely to the climate change field treatments, indicating that species composition is important when analyzing climate change effects on grassland C cycling. Root biomass in the C3 sedge, C. eleocharis, increased under elevated CO2, especially when combined with warming. Decomposition rates of roots from warming plots were higher than those from ambient plots for B. gracilis and P. smithii. Across species, root decomposition rates increased with C and N concentrations. Root morphology was altered as well: B. gracilis root diameter increased under warming, and P. smithii specific root length and surface area increased under elevated CO2. P. smthii roots induced short-term, negative SOC priming across all field treatments. Together, our results indicate that grass roots may play a critical role in maintaining soil C stocks in grasslands in the future.