碱度
风化作用
碳酸盐
碳循环
碳酸盐岩
地质学
碳酸盐矿物
碳纤维
溶解
地球化学
无机碳总量
矿物学
环境化学
化学
二氧化碳
作者
Pouyan Asem,B. B. Guzina,J. F. Labuz
标识
DOI:10.1680/jgele.25.00072
摘要
The chemical weathering of ultramafic rocks by carbon dioxide–bearing fluids contributes to the geologic carbon cycle through carbonate alkalinity production. Experiments were conducted on a fresh feldspathic lherzolite from Tamarack, Minnesota, USA, and a serpentinised harzburgite from the Semail ophiolite, Oman, to investigate the dependence of chemical weathering and carbonate alkalinity on the (i) initial serpentinisation extent, (ii) rock microstructural characteristics and (iii) initial rock/water ratio. The experiments on the granulated Tamarack feldspathic lherzolite with a large rock/water ratio showed the (i) rock weathering increased pH to 9·5, which stabilised at 8·5 as fluid residence time increased, (ii) rock chemical weathering produced carbonate alkalinity by developing favourable pH conditions and (iii) dissolution rate decreased following cycles of carbon-bearing fluid injection. Analysis of feldspathic lherzolite weathering products after some 2500 h of reaction showed (i) the carbonate and hydrated carbonate minerals were not detectable for experiments with both large and small rock/water ratios and (ii) phyllosilicate minerals (talc and chrysotile) formed during the experiment with a large rock/water ratio. Comparison with experiments on serpentinised harzburgite from Oman (intact) and feldspathic lherzolite from the USA (intact and granulated), all with smaller available reactive surface areas, suggests that a decrease in the rock/water ratio and an increase in serpentinisation extent reduced reaction rates.
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