Contribution of leaf and needle litter to whole ecosystem BVOC fluxes: Fid-Bau Portal

Contribution of leaf and needle litter to whole ecosystem BVOC fluxes

Greenberg, J.P. / Asensio, D. / Turnipseed, A. / Guenther, A.B. / Karl, T. / Gochis, D.

Abstract Biogenic volatile organic compound (BVOC) emissions come from a variety of sources, including living above-ground foliar biomass and microbial decomposition of dead organic matter at the soil surface (litter and soil organic matter). There are, however, few reports that quantify the contributions of each component. Measurements of emission fluxes are now made above the vegetation canopy, but these include contributions from all sources. BVOC emission models currently include detailed parameterization of the emissions from foliar biomass but do not have an equally descriptive treatment of emissions from litter or other sources. We present here results of laboratory and field experiments to characterize the major parameters that control emissions from litter. Litter emissions are exponentially dependent on temperature. The moisture content of the litter plays a minor role, except during and immediately following rain events. The percentage of carbon readily available for microbial and other decomposition processes decreases with litter age. These 3 variables are combined in a model to explain over 50% of the variance of individual BVOC emission fluxes measured. The modeled results of litter emissions were compared with above-canopy fluxes. Litter emissions constituted less than 1% of above-canopy emissions for all BVOCs measured. A comparison of terpene oil pools in litter and live needles with above-canopy fluxes suggests that there may be another canopy terpene source in addition to needle storage or that some terpene emissions may be light-dependent. Ground enclosure measurements indicated that compensation point concentrations of BVOCs (equilibrium between BVOC emission and deposition) were usually higher than ambient air concentrations at the temperature of the measurements.

Highlights ► Litter BVOC fluxes were measured by gradient flux and enclosure techniques. ► Emissions were shown to have exponential dependence on temperature and moisture. ► A litter BVOC emissions model was developed which successfully reproduced the emission measurements. ► Litter BVOC emissions make only a small contribution to the whole ecosystem flux of the BVOCs measured.