Title
Exposure to warming and <tex>$CO_{2}$</tex> enrichment promotes greater above-ground biomass, nitrogen, phosphorus and arbuscular mycorrhizal colonization in newly established grasslands Exposure to warming and <tex>$CO_{2}$</tex> enrichment promotes greater above-ground biomass, nitrogen, phosphorus and arbuscular mycorrhizal colonization in newly established grasslands
Author
Faculty/Department
Faculty of Sciences. Biology
Publication type
article
Publication
's-Gravenhage ,
Subject
Biology
Source (journal)
Plant and soil. - 's-Gravenhage
Volume/pages
359(2012) :1-2 , p. 121-136
ISSN
0032-079X
ISI
000308960800010
Carrier
E
Target language
English (eng)
Full text (Publishers DOI)
Affiliation
University of Antwerp
Abstract
Aims In view of the projected increase in global air temperature and CO2 concentration, the effects of climatic changes on biomass production, CO2 fluxes and arbuscular mycorrhizal fungi (AMF) colonization in newly established grassland communities were investigated. We hypothesized that above- and below-ground biomass, gross primary productivity (GPP), AMF root colonization and nutrient acquisition would increase in response to the future climate conditions. Furthermore, we expected that increased below-ground C allocation would enhance soil respiration (Rsoil). Methods Grassland communities were grown either at ambient temperatures with 375 ppm CO2 (Amb) or at ambient temperatures +3°C with 620 ppm CO2 (T+CO2). Results Total biomass production and GPP were stimulated under T+CO2. Above-ground biomass was increased under T+CO2 while belowground biomass was similar under both climates. The significant increase in root colonization intensity under T+CO2, and therefore the better contact between roots and AMF, probably determined the higher above-ground P and N content. Rsoil was not significantly affected by the future climate conditions, only showing a tendency to increase under future climate at the end of the season. Conclusions Newly established grasslands benefited from the exposure to elevated CO2 and temperature in terms of total biomass production; higher root AMF colonization may partly provide the nutrients required to sustain this growth response.
E-info
https://repository.uantwerpen.be/docman/iruaauth/1f4e3a/1d533c06a60.pdf
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