Carbonate caprock-brine-CO2 interaction: alteration of hydromechanical properties

Guijie Sang, Shimin Liu

Research output: Contribution to conferencePaperpeer-review

Abstract

Caprocks play a crucial role in geological storage of CO2 by preventing the escape of CO2 and thus trapping CO2 into underlying porous reservoirs. An evaluation of interaction-induced alteration of hydromechanical properties of caprocks are essential to better assess the leaking risk and injection-induced rock instability, and thus ensuring a long-term viability of geological CO2 storage. We study the changes in nanopores, elastic velocities and mechanical responses of a carbonate caprock due to rock-water/brine-CO2 interaction (CO2 pressure ~ 12 MPa; 50 ℃). Before the interaction, the total and accessible porosities are 1.6% and 0.6%, respectively, as characterized by the Small Angle Neutron Scattering (SANS) technique. SANS results show that the total porosity of the carbonate caprock increases apparently due to rock-brine-CO2 interaction and the increasing rate rises as brine concentration increases (2.2% for 0M NaCl, 2.6% for 1M NaCl, and 2.7% for 4M NaCl). The increase total porosity is due to the dissolution of calcite which tends to enlarge accessible pores (by 0.8%-1.2%) while slightly decrease the inaccessible pores (by 0.1%-0.2%). Under CO2-acidified water environment, P- and S-wave velocities (5536.7 m/s and 2699.7 m/s) of a core sample containing natural fractures decreases by 8.5% and 8.1% respectively, while both P- and S-wave velocities (6074.1 m/s and 3858.8 m/s) for a intact sample show only ~0.5% decreases. The interaction also causes more than 50% degradation of the uniaxial compressive strength for the core sample with natural fractures.
Original languageEnglish
DOIs
Publication statusPublished - 19 Oct 2020
EventSPE Annual Technical Conference and Exhibition 2020 - Virtual, Virtual
Duration: 26 Oct 202029 Oct 2020

Conference

ConferenceSPE Annual Technical Conference and Exhibition 2020
CityVirtual
Period26/10/2029/10/20

Keywords

  • hydromechanical properties
  • production monitoring
  • shale gas
  • chemical flooding methods
  • flow in porous media
  • reservoir characterization
  • enhanced recovery
  • hydraulic fracturing
  • complex reservoir
  • upstream oil & gas
  • reservoir simulation

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