Abstract
Abstract. CO2 exchange between terrestrial ecosystems and the atmosphere is key to understanding the feedbacks between climate change and the land surface. In regions with carbonaceous parent material, CO2 exchange patterns occur that cannot be explained by biological processes, such as disproportionate outgassing during the daytime or nighttime CO2 uptake during periods when all vegetation is senescent. Neither of these phenomena can be attributed to carbonate weathering reactions, since their CO2 exchange rates are too small. Soil ventilation induced by high atmospheric turbulence is found to explain atypical CO2 exchange between carbonaceous systems and the atmosphere. However, by strongly altering subsurface CO2 concentrations, ventilation can be expected to influence carbonate weathering rates. By imposing ventilation-driven CO2 outgassing in a carbonate weathering model, we show here that carbonate geochemistry is accelerated and does play a surprisingly large role in the observed CO2 exchange pattern of a semi-arid ecosystem. We found that by rapidly depleting soil CO2 during the daytime, ventilation disturbs soil carbonate equilibria and therefore strongly magnifies daytime carbonate precipitation and associated CO2 production. At night, ventilation ceases and the depleted CO2 concentrations increase steadily. Dissolution of carbonate is now enhanced, which consumes CO2 and largely compensates for the enhanced daytime carbonate precipitation. This is why only a relatively small effect on global carbonate weathering rates is to be expected. On the short term, however, ventilation has a drastic effect on synoptic carbonate weathering rates, resulting in a pronounced diel pattern that exacerbates the non-biological behavior of soil–atmosphere CO2 exchanges in dry regions \\mbox{with carbonate soils}.
Highlights
The net carbon balance of ecosystems has become a key focus in the study of the global carbon cycle
The dashed line shows a typical day in the dry season, showing that geochemical fluxes are slightly larger than in the wet season, due to a larger relative difference in soil water content (SWC) between night and day
We evaluated the role of ventilation in modifying the chemical weathering rates at annual timescale and found that our model simulated, for the site under study, a reduction in net CO2 uptake by carbonate dissolution of 16 % (4 g C m−2 yr−1)
Summary
The net carbon balance of ecosystems has become a key focus in the study of the global carbon cycle. The assessment of net ecosystem CO2 fluxes on different scales of time and space is enabled through eddy covariance measurements that are being performed on “flux towers” around the globe (Baldocchi et al, 2001). These net CO2 exchanges with the atmosphere are interpreted as the sum of the photosynthetic and respiratory components, while little is known about the role of geological carbon cycling in the soil– atmosphere CO2 exchange. Given that carbonate systems cover more than 10 % of the world’s land surface (Durr et al, 2005), the hypothesized important contribution of carbonate weathering to the CO2 flux measurements needs to be tested
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
