Field-case simulation of CO2 -plume migration using vertical-equilibrium models

When injected in deep saline aquifers, CO2 moves radially away from the injection well and progressively higher in the formation because of buoyancy forces. Analyzes have shown that after the injection period, CO2 will potentially migrate over several kilometers in the horizontal direction but only tens of meters in the vertical direction, limited by the aquifer caprock [1, 2]. Because of the large horizontal plume dimensions, three-dimensional numerical simulations of the plume migration over long periods of time are computationally intensive. Thus, to get results within a reasonable time frame, one is typically forced to use coarse meshes and long time steps which result in inaccurate results because of numerical errors in resolving the plume tip. Given the large aspect ratio between the vertical and horizontal plume dimensions, it is reasonable to approximate the CO2 migration using vertically averaged models. Such models can, in many cases, be more accurate than coarse three-dimensional computations. In particular, models based on vertical equilibrium (VE) [3] are attractive to simulate the long-term fate of CO2 sequestered into deep saline aquifers. The reduced spatial dimensionality resulting from the vertical integration ensures that the computational performance of VE models exceeds the performance of standard three-dimensional models. Thus, VE models are suitable to study the long-time and large-scale behavior of plumes in real large-scale CO2-injection projects [4, 1, 2, 5]. We investigate the use of VE models to simulate CO2 migration in a real large-scale eld case based on data from the Sleipner site in the North Sea. We discuss the potential and limitations of VE models and show how VE models can be used to give reliable estimates of long-term CO2 migration. In particular, we focus on a VE formulation that incorporates the aquifer geometry and heterogeneity, and that considers the eects of hydrodynamic and residual trapping. We compare the results of VE simulations with standard reservoir simulation tools on test cases and discuss their advantages and limitations and show how, provided that certain conditions are met, they can be used to give reliable estimates of long-term CO2 migration.

[1]  J. Molenaar,et al.  A Fast 3D Interface Simulator for Steamdrives , 1999 .

[2]  Hamdi A. Tchelepi,et al.  Gravity currents in horizontal porous layers: transition from early to late self-similarity , 2007, Journal of Fluid Mechanics.

[3]  M. A. Hessea,et al.  Gravity Currents with Residual Trapping , 2009 .

[4]  C. H. Neuman A Gravity Override Model of Steamdrive , 1985 .

[5]  Jan M. Nordbotten,et al.  Geological Storage of CO2: Modeling Approaches for Large-Scale Simulation , 2011 .

[6]  K. H. Coats,et al.  Simulation of three-dimensional, two-phase flow in oil and gas reservoirs , 1967 .

[7]  L. V. D. Meer,et al.  Monitoring of CO2 injected at Sleipner using time-lapse seismic data , 2004 .

[8]  Jan M. Nordbotten,et al.  Vertical equilibrium with sub-scale analytical methods for geological CO2 sequestration , 2009 .

[9]  Halvor Møll Nilsen,et al.  Numerical Aspects of Using Vertical Equilibrium Models for Simulating CO2 Sequestration , 2010 .

[10]  Ruben Juanes,et al.  Post-injection spreading and trapping of CO2 in saline aquifers: impact of the plume shape at the end of injection , 2009 .

[11]  Andy Chadwick,et al.  Axisymmetric gravity currents in a porous medium , 2005, Journal of Fluid Mechanics.

[12]  N. W. Lanfredi,et al.  HP 67/97 calculator waves application programs , 1987 .

[13]  Andy Chadwick,et al.  Modelling carbon-dioxide accumulation at Sleipner: implications for underground carbon storage , 2007 .

[14]  Andrew W. Woods,et al.  Gravity-driven flows in porous layers , 1995, Journal of Fluid Mechanics.

[15]  John C. Martin Partial Integration of Equations of Multiphase Flow , 1968 .

[16]  Sam Holloway,et al.  Geological reservoir characterization of a CO2 storage site: The Utsira Sand, Sleipner, northern North Sea , 2004 .

[17]  Dmitri Kavetski,et al.  Model for CO2 leakage including multiple geological layers and multiple leaky wells. , 2009, Environmental science & technology.

[18]  Herbert E. Huppert,et al.  Gravity currents in a porous medium at an inclined plane , 2006, Journal of Fluid Mechanics.

[19]  Jan M. Nordbotten,et al.  Impact of the capillary fringe in vertically integrated models for CO2 storage , 2011 .

[20]  L. Lake,et al.  Enhanced Oil Recovery , 2017 .

[21]  Laurent Trenty,et al.  A benchmark study on problems related to CO2 storage in geologic formations , 2009 .

[22]  Ruben Juanes,et al.  The Footprint of the CO2 Plume during Carbon Dioxide Storage in Saline Aquifers: Storage Efficiency for Capillary Trapping at the Basin Scale , 2010 .

[23]  Bamshad Nazarian,et al.  Reservoir Modeling of CO2 Plume Behavior Calibrated Against Monitoring Data From Sleipner, Norway , 2010 .