CO2 diffusion into pore spaces limits weathering rate of an experimental basalt landscape

Basalt weathering is a key control over the global carbon cycle, though in situ measurements of carbon cycling are lacking. In an experimental, vegetation-free hillslope containing 330 m3 of ground basalt scoria, we measured real-time inorganic carbon dynamics within the porous media and seepage flo...

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Bibliographic Details
Published in:Geology (Boulder) 2017-03, Vol.45 (5), p.422-422
Main Authors: van Haren, Joost, Dontsova, Katerina, Barron-Gafford, Greg A, Troch, Peter A, Chorover, Jon, Delong, Stephen B, Breshears, David D, Huxman, Travis E, Pelletier, Jon D, Saleska, Scott R, Xeng, Xubin, Ruiz, Joaquin
Format: Article
Language:English
Subjects:
atmospheric precipitation
basalts
carbon
carbon cycle
carbon dioxide
concentration
diffusion
experimental studies
geochemical cycle
Geochemistry
igneous and metamorphic rocks
igneous rocks
Petrology
pore water
porous materials
rain
seepage
volcanic rocks
weathering
weathering rates
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Summary:Basalt weathering is a key control over the global carbon cycle, though in situ measurements of carbon cycling are lacking. In an experimental, vegetation-free hillslope containing 330 m3 of ground basalt scoria, we measured real-time inorganic carbon dynamics within the porous media and seepage flow. The hillslope carbon flux (0.6-5.1 mg C m-2 h-1) matched weathering rates of natural basalt landscapes (0.4-8.8 mg C m-2 h-1) despite lacking the expected field-based impediments to weathering. After rainfall, a decrease in CO2 concentration ([CO2]) in pore spaces into solution suggested rapid carbon sequestration but slow reactant supply. Persistent low soil [CO2] implied that diffusion limited CO2 supply, while when sufficiently dry, reaction product concentrations limited further weathering. Strong influence of diffusion could cause spatial heterogeneity of weathering even in natural settings, implying that modeling studies need to include variable soil [CO2] to improve carbon cycling estimates associated with potential carbon sequestration methods.
ISSN:0091-7613
1943-2682
DOI:10.1130/G38569.1