Responses of canopy and soil climate in a six year free-air CO2 enrichment study with spring crops

Publication Type

Journal contribution (peer reviewed)

Authors

Franzaring, J., Högy, P., Erbs, M., Fangmeier, A.

Year of publication

2010

Published in

Agricultural and Forest Meteorology

Band/Volume

150/

Page (from - to)

354-360

<!-- /* Style Definitions */ p.MsoNormal, li.MsoNormal, div.MsoNormal {mso-style-parent:""; margin:0cm; margin-bottom:.0001pt; mso-pagination:widow-orphan; font-size:12.0pt; font-family:"Times New Roman"; mso-fareast-font-family:"Times New Roman"; mso-fareast-language:DE;} @page Section1 {size:612.0pt 792.0pt; margin:70.85pt 70.85pt 2.0cm 70.85pt; mso-header-margin:36.0pt; mso-footer-margin:36.0pt; mso-paper-source:0;} div.Section1 {page:Section1;} --> Besides increased growth, plants cultivated under elevated CO₂ show reduced transpiration and improved water use efficiency due to decreased stomatal conductances. While growth profits from the longer availability of soil water under CO₂-enrichment, increased canopy temperature may counteract these positive effects. Here we report on time series of soil temperatures and moistures from six years in which spring crops were cultivated in free-air CO₂ enrichment (Mini-FACE) experiments. Besides air and soil climate, temperature and relative humidity were determined in wheat canopies. Measurements rested on five replicates per treatment, representing a control (CON), an ambient air (AMB) and a FACE treatment. While the CON and AMB plots did not receive additional CO₂, concentrations were moderately elevated by 150 µl l^-1 in the FACE plots. Plant growth differed among years due to the different climate and duration of individual experiments. Total biomass production was significantly increased in the FACE treatments only in two out of six years. In most of the years, soil temperatures tended to be reduced and soil moistures remained higher under elevated CO₂. Because the observed differences recurred during the growing season, we conclude that CO₂ enrichment was responsible for changes of the soil microclimate. At the same time vapour pressure deficit in the canopy significantly differed between the treatments for some days. While canopy heating due to CO₂ enrichment occurred in the early growing season these effects disappeared later suggesting that the stronger increase in leaf area index in the FACE treatments mitigated heating effects over time. The results support the supposed effects of CO₂ enrichment on the canopy climate and indicate a ´microclimatic paradox´ with higher soil water availability due to the reduced transpiration and stronger canopy heating in FACE plots at least early in the season.