2009 Portland GSA Annual Meeting (18-21 October 2009)

Paper No. 16
Presentation Time: 9:00 AM-6:00 PM

EXPERIMENTAL SIMULATION OF CO2-WATER-ROCK INTERACTIONS FOR CARBON SEQUESTRATION AND ENHANCED OIL RECOVERY IN NORTH DAKOTA WILLISTON BASIN


ZENG, Zhengwen1, ZHOU, Xuejun2, BOOCK, Alyssa1 and LIU, Hong2, (1)Geology and Geological Engineering, University of North Dakota, 81 Cornell St, Stop 358, Grand Forks, ND 58202, (2)Geology and Geological Engineering, University of North Dakota, 81 Cornell St, Stop 8358, Grand Forks, ND 58202, zeng@und.nodak.edu

Carbon dioxide (CO2) is injected to deep geological formations mainly for two purposes: CO2 enhanced oil recovery (EOR) and CO2 sequestration. The injection of into carbonate reservoirs and aquifers causes pore water to change pH. The lowering of pore water pH causes a reaction between the carbonic acid and carbonate rocks, which can change porosity, permeability, fluid chemistry, seismic velocity, and mechanical properties. With the increase in consideration for CO2 enhanced oil recovery and CO2 geologic sequestration within the basin, laboratory testing is necessary to limit reservoir damage and maximize oil production and/or CO2 storage. The University of North Dakota Petroleum Engineering Laboratory developed a testing system that can be used to simulate the CO2-water-rock interaction under deep reservoir conditions. Because much of the North Dakota Williston Basin hydrocarbon production comes from carbonate reservoirs, and there are only limited reservoir core samples available for extensive laboratory testing, Indiana Limestone is used as a standard for the tests, due to its uniform composition, texture, and structure. Different combinations of fluid injection scheme (CO2-water ratio, injection rate, total injection volume, and pressure, etc) have been tested. Changes of rock porosity, permeability, seismic velocity, and geomechanical properties, as well as effluent geochemistry (pH, total dissolved solids, conductivity, etc) have been observed. This paper presents some of our initial analysis, and their impact on CO2 sequestration and enhanced oil recovery.