We have set up a facility allowing steady state ¹³CO₂ labeling of short stature vegetation (12 m²) for several years. ¹³C labelling is obtained by scrubbing the CO₂ from outdoors air with a self-regenerating molecular sieve and by replacing it with ¹³C depleted (-34.7±0.03‰) fossil-fuel derived CO₂ The facility, which comprises 16 replicate mesocosms, allows tracing the fate of photosynthetic carbon in plant-soil systems in natural light and at outdoors temperature.

This method was applied during 2 yrs to temperate grassland monoliths (0.5×0.5×0.4 m) sampled in a long term grazing experiment. During daytime, the canopy enclosure in each mesocosm was supplied in an open flow (0.67–0.88 volume per minute) with modified air (43% scrubbed air and 57% cooled and humidified ambient air) at mean CO₂ concentration of 425 µmol mol^-1 and d¹³C of -21.5±0.27‰. Above and belowground CO₂ fluxes were continuously monitored. The difference in d¹³C between the CO₂ at the outlet and at the inlet of each canopy enclosure was not significant (-0.35±0.39‰). Due to mixing with outdoors air, the CO₂ concentration at enclosure inlet followed a seasonal cycle, often found in urban areas, where d¹³C of CO₂ is lower in winter than in summer. Mature C₃ grass leaves were sampled monthly in each mesocosm, as well as leave from pot-grown control C₄ (Paspalum dilatatum). The mean d¹³C of fully labelled C₃ and C₄ leaves reached -41.4±0.67 and -28.7±0.39‰ respectively. On average, the labelling reduced by 12.7‰ the d¹³C of C₃ grass leaves. The isotope mass balance technique was used to calculate the fraction of "new" C in the soil organic matter (SOM) above 0.2 mm. A first order exponential decay model fitted to "old" C data showed that reducing aboveground disturbance by cutting increased from 22 to 31 months the mean residence time of belowground organic C (>0.2 mm) in the top soil.