K. de Kloe scite author profile

Drying and salt precipitation in geological formations can have serious consequences for upstream operations in terms of injectivity and productivity. Here we investigate the consequences of supercritical CO 2 injection in sandstones. The reported findings are directly relevant for CO 2 sequestration and acid-gas injection operations, but might also be of interest to a broader community dealing with drying and capillary phenomena. By injecting dry supercritical CO 2 into brine-saturated sandstone, we investigate the drying process and the associated precipitation of salts in a capillary-pressure-dominated flow regime. Precipitation patterns were recorded during the drying process by means of CT scanning. The experimental results and numerical simulations show that under a critical flow rate salt precipitates with an inhomogeneous spatial distribution because of brine and solutes being transported in counter-current flow upstream where salt eventually precipitates. A substantial impairment of the absolute permeability has been found, but despite high local salt accumulation, the effective CO 2 permeability increased during all experiments. This phenomenon is a result of the observed microscopic precipitation pattern and eventually the resulting K() relationship. The findings in this paper are related to unimodal sandstone. In a companion paper (Ott et al., 2014) we present data on the distinctly different consequences of salt precipitation in dual-or multi-porosity rocks.

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Injection of supercritical CO2 in brine saturated sandstone: Pattern formation during salt precipitation

Ott

Kloe

Marcelis

et al. 2011

Energy Procedia

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Salt Precipitation Due to Sc-gas Injection: Single Versus Multi-porosity Rocks

et al. 2013

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Core-flood experiment for transport of reactive fluids in rocks

Ott

Kloe

Bakel

et al. 2012

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Investigation of the transport of reactive fluids in porous rocks is an intriguing but challenging task and relevant in several areas of science and engineering such as geology, hydrogeology, and petroleum engineering. We designed and constructed an experimental setup to investigate physical and chemical processes caused by the flow of reactive and volatile fluids such as supercritical CO(2) and/or H(2)S in geological formations. Potential applications are geological sequestration of CO(2) in the frame of carbon capture and storage and acid-gas injection for sulfur disposal and/or enhanced oil recovery. The present paper outlines the design criteria and the realization of reactive transport experiments on the laboratory scale. We focus on the spatial and time evolution of rock and fluid composition as a result of chemical rock fluid interaction and the coupling of chemistry and fluid flow in porous rocks.

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Salt precipitation due to supercritical gas injection: II. Capillary transport in multi porosity rocks

Ott

Snippe

Kloe

2021

International Journal of Greenhouse Gas Control

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K. de Kloe

Salt precipitation due to supercritical gas injection: I. Capillary-driven flow in unimodal sandstone

Injection of supercritical CO2 in brine saturated sandstone: Pattern formation during salt precipitation

Salt Precipitation Due to Sc-gas Injection: Single Versus Multi-porosity Rocks

Core-flood experiment for transport of reactive fluids in rocks

Salt precipitation due to supercritical gas injection: II. Capillary transport in multi porosity rocks

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