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Altered root traits due to elevated CO 2 : a meta‐analysis
Author(s) -
Nie Ming,
Lu Meng,
Bell Jennifer,
Raut Swastika,
Pendall Elise
Publication year - 2013
Publication title -
global ecology and biogeography
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.164
H-Index - 152
eISSN - 1466-8238
pISSN - 1466-822X
DOI - 10.1111/geb.12062
Subject(s) - biomass (ecology) , biology , root system , shoot , ecosystem , nutrient , botany , horticulture , ecology
Aim Plant root traits regulate belowground C inputs, soil nutrient and water uptake, and play critical roles in determining sustainable plant production and consequences for ecosystem C storage. However, the effects of elevated CO 2 on root morphology and function have not been well quantified. We reveal general patterns of root trait responses to elevated CO 2 from field manipulative experiments. Location N orth A merica, E urope, O ceania, A sia. Methods The meta‐analysis approach was used to examine the effects of CO 2 elevation on 17 variables associated with root morphology, biomass size and distribution, C and N concentrations and pools, turnover and fungal colonization from 110 published studies. Results Elevated CO 2 increased root length (+26.0%) and diameter (+8.4%). Elevated CO 2 also stimulated total root (+28.8%), fine root (+27.7%) and coarse root biomass (+25.3%), demonstrating strong responses of root morphology and biomass. Elevated CO 2 increased the root:shoot ratio (+8.5%) and decreased the proportion of roots in the topsoil (–8.4%), suggesting that plants expand rooting systems. In addition, elevated CO 2 decreased N concentration (–7.1%), but did not affect C concentration, and thus increased the C : N ratio (+7.8%). Root C (+29.3%) increased disproportionately relative to root N pools (+9.4%) under elevated CO 2 . Functional traits were also strongly affected by elevated CO 2 , which increased respiration (+58.9%), rhizodeposition (+37.9%) and fungal colonization (+3.3%). Main conclusions These results suggest that elevated CO 2 promoted root morphological development, root system expansion and C input to soils, implying that the sensitive responses of root morphology and function to elevated CO 2 would increase long‐term belowground C sequestration.

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