Abstract

The study of the fate of assimilated carbon in respiratory fluxes in the field is needed to resolve the residence and transfer times of carbon in the atmosphereplant-soil system in forest ecosystems, but it requires high frequency measurements of the isotopic composition of evolved CO 2 . We developed a closed transparent chamber to label the whole crown of a tree and a labelling system capable of delivering a 3-h pulse of 99% 13 CO 2 in the field. The isotopic compositions of trunk and soil CO 2 effluxes were recorded continuously on two labelled and one control trees by a tuneable diode laser absorption spectrometer during a 2-month chase period following the late summer labelling. The lag times for trunk CO 2 effluxes are consistent with a phloem sap velocity of about 1 m h 1 . The isotopic composition (d 13 C) of CO 2 efflux from the trunk was maximal 2-3 days after labelling and declined thereafter following two exponential decays with a half-life of 2-8 days for the first and a half-life of 15-16 days for the second. The isotopic composition of the soil CO 2 efflux was maximal 3-4 days after labelling and the decline was also well fitted with a sum of two exponential functions with a half-life of 3-5 days for the first exponential and a half-life of 16-18 days for the second. The amount of label recovered in CO 2 efflux was around 10-15% of the assimilated 13 CO 2 for soil and 5-13% for trunks. As labelling occurred late in the growing season, substantial allocation to storage is expected.