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The subcontinental lithospheric mantle (SCLM) is a potentially significant but poorly constrained carbon reservoir. In this study, the accumulation of CO 2 in the SCLM beneath the Bakony–Balaton Highland Volcanic Field (BBHVF), Hungary, was quantified during the post-rift evolution of the Pannonian Basin (10 Ma - today). Using 167 upper mantle xenoliths with known sampling ages by the host basalts, and their equilibrium temperatures, their depth of origin was derived based on newly modelled paleogeotherms for 2, 4.5, and 8 Ma. Our findings demonstrate that peridotite xenoliths encompass the entire vertical range of the SCLM (34–69 km), indicating a depth dichotomy between equigranular textures, which are found at shallower depths (37–55 km), and protogranular textures, which occur at greater depths (52–68 km). In other words, the xenoliths proved to represent full-depth SCLM sampling. According to xenolith textures, a progressive deepening trend of protogranular xenoliths through time reflects lithospheric thickening during the post-rift phase. We estimate CO 2 accumulation within newly accreted lithospheric mantle volumes using diverse density and CO 2 content scenarios. The most probable scenario (2000 ppm CO 2 , 3.2 g/cm 3 SCLM density) suggests an average CO 2 accumulation rate of ~3700–16,300 tons/year in the BBHVF area (25 × 40 km), with a total of ~103 Gt over 10 million years. Our calculations showed that the contribution of deep mantle CO 2 to carbon budget could be more significant than expected. Our results provide essential constraints on long-term carbon cycling within the evolving continental lithosphere, supporting a more accurate global carbon budget model. • Xenoliths reveal full-depth SCLM sampling. • Depth trends show lithospheric thickening during post-rift basin evolution. • CO 2 accumulation estimated at ~103 Gt in 10 Ma beneath BBHVF. • Geological CO 2 flux could be more significant than expected.
Hencz et al. (Sun,) studied this question.