Name:CHENG Xiaoli
Tell:
Email:xlcheng@fudan.edu.cn
Organization:Wuhan Botanical Garden
Researchers Cooperates to Evaluated Rhizospheric Carbon-Nitrogen Interactions
2016-11-28
Rhizospheric processes are more biogeochemically active between plant and soil systems and appear to be more responsive to environmental change than bulk soil processes. A better understanding of rhizosphere carbon (C) and nitrogen (N) interactions under elevated carbon dioxide (CO2 ) is essential for accurately predicting long-term C fixation in terrestrial ecosystems under future climate change. The responses of rhizospheric processes to elevated CO2 vary across mono-species studies, yet our understanding of the responses of multiple co-occurring species is still limited.
Prof. CHENG Xiaoli from Wuhan Botanical Garden, Cooperated with New Zealand AgResearch Grasslands, conducted a field study using the New Zealand free-air CO2 enrichment (FACE) experiment to evaluate rhizospheric C and N dynamics in a low-fertility species (Agrostiscapillaris) and a high-fertility species (Loliumperenne) under 13 years of elevated CO2 and at ambient levels.
Study demonstrated that the responses of the two species to elevated CO2 differed in terms of growth, with a positive response for L. perenne and a negative response for A. capillaris. Despite contrasting responses of plant growth, elevated CO2 significantly increased the total C and N (TC and TN, respectively), net N mineralization and nitrification rates in the rhizospheres across species. However, the rhizospheric microbial biomass C (MBC) was significantly enhanced for L. perenne but reduced for A. capillarisunder elevated CO2. Elevated CO2 did not affect rhizospheric NO3--N concentrations for either species, while it significantly increased the rhizospheric NH4+-N concentration for A. capillaris.
Together, the increased TC as well as the decreased MBC suggested rhizosphere in A. capillaris may be more favorable to long term C sequestration under elevated CO2. The increased NH4+-N concentration may stimulate the growth of A. capillaris under elevated CO2 in the near future, which will have significant implication for the change in species composition.
The findings in this study are useful for parameterizing terrestrial biogeochemical models with mixed-species ecosystems, which can be used to analyze the effects of possible future climate change.
This research was financially supported by the National Natural Science Foundation of China and the “Strategic Priority Research Program-Climate Change: Carbon Budget and Relevant Issues” of the Chinese Academy of Sciences.
Results have been published in Agriculture, Ecosystems and Environment “Rhizospheric carbon-nitrogen interactions in a mixed-species pasture after 13 years of elevated CO2” .
Above-ground plant biomass (dry weight, g m-2) (a), plant N (b) and P (c) concentration and C: N ratio (d) affected by plant species and atmospheric CO2 treatment. Error bars represent standard errors. Different letters above the bars indicate significant differences (p<0.05). (Image by CHENG’s group)