Journal Article10.2475/AJS.294.5.529
A coupled model for transport of multiple chemical species and kinetic precipitation/dissolution reactions with application to reactive flow in single phase hydrothermal systems
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About: This article is published in American Journal of Science. The article was published on 01 May 1994. The article focuses on the topics: Hydrothermal circulation & Dissolution.
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Citations
TOUGHREACT-A simulation program for non-isothermal multiphase reactive geochemical transport in variably saturated geologic media: Applications to geothermal injectivity and CO2 geological sequestration
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889
Chemical weathering rate laws and global geochemical cycles
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Reactive transport codes for subsurface environmental simulation
Carl I. Steefel,C. A. J. Appelo,Bhavna Arora,Diederik Jacques,Thomas Kalbacher,Olaf Kolditz,Vincent Lagneau,Peter C. Lichtner,K. U. Mayer,Johannes C. L. Meeussen,Sergi Molins,David Moulton,Haibing Shao,Jirka Šimůnek,Nicolas Spycher,Steven B. Yabusaki,Gour Tsyh Yeh +16 more
TL;DR: A general description of the mathematical and numerical formulations used in modern numerical reactive transport codes relevant for subsurface environmental simulations is presented, along with a selective list of applications that highlight their capabilities and historical development.
Reactive transport modeling: An essential tool and a new research approach for the Earth sciences
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692
Numerical simulation of CO2 disposal by mineral trapping in deep aquifers
TL;DR: In this article, the authors analyzed the impact of CO2 immobilization through carbonate mineral precipitation in aquifers, and found that the amount of CO 2 that may be sequestered by precipitation of secondary carbonates is comparable with and can be larger than the effect of dissolution in pore waters.
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