Abstract
AbstractResearch on the subterranean CO2 dynamics has focused individually on either surface soils or bedrock cavities, neglecting the interaction of both systems as a whole. In this regard, the vadose zone contains CO2‐enriched air (ca. 5% by volume) in the first meters, and its exchange with the atmosphere can represent from 10 to 90% of total ecosystem CO2 emissions. Despite its importance, to date still lacking are reliable and robust databases of vadose zone CO2 contents that would improve knowledge of seasonal‐annual aboveground‐belowground CO2 balances. Here we study 2.5 years of vadose zone CO2 dynamics in a semiarid ecosystem. The experimental design includes an integrative approach to continuously measure CO2 in vertical and horizontal soil profiles, following gradients from surface to deep horizons and from areas of net biological CO2 production (under plants) to areas of lowest CO2 production (bare soil), as well as a bedrock borehole representing karst cavities and ecosystem‐scale exchanges. We found that CO2 followed similar seasonal patterns for the different layers, with the maximum seasonal values of CO2 delayed with depth (deeper more delayed). However, the behavior of CO2 transport differed markedly among layers. Advective transport driven by wind induced CO2 emission both in surface soil and bedrock, but with negligible effect on subsurface soil, which appears to act as a buffer impeding rapid CO2 exchanges. Our study provides the first evidence of enrichment of CO2 under plant, hypothesizing that CO2‐rich air could come from root zone or by transport from deepest layers through cracks and fissures.
Highlights
Knowledge about the production and transport of CO2 within the vadose zone remains very vague
The transect from below plant to bare soil showed that during windy days, CO2 molar fraction increased exclusively in the sensor located under the plant
Soil CO2 effluxes emitted to the atmosphere from under plant were greater than on calm days, whereas emissions from bare soil were reduced
Summary
Knowledge about the production and transport of CO2 within the vadose zone remains very vague. High-frequency data logging has produced reliable annual carbon balances around the world, generating vast databases with special interest for modeling and upscaling studies [Reichstein et al, 2005; Schwalm et al, 2010; Groenendijk et al, 2011; Lasslop et al, 2012; Stoy et al, 2013]. Besides this global monitoring network, few studies have been designed to monitor continuously the CO2 exchanges from the soil, despite their representing an important contribution (10–90%) of total ecosystem CO2 emissions [Hanson et al, 2000; Curiel Yuste et al, 2005]. Despite their contribution to annual carbon balances, coherent and continuous databases of soil CO2 effluxes still do not exist [Gomez-Casanovas et al, 2013]
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