[摘要] We derive a theoretical model for the post-injection migration of a CO[subscript 2] gravity current in a confined, sloping aquifer under the influence of residual trapping, solubility trapping, and capillary pinning. The resulting model consists of two coupled partial differential equations that describe the local thickness of the buoyant CO[subscript 2] current and the thickness of the mound of brine saturated with dissolved CO[subscript 2] as a function of time. We apply this model to a representative geological formation and provide estimates of the lifetime of the buoyant CO[subscript 2] current and its maximum migration distance. Our analysis shows that residual trapping, solubility trapping, and capillary pinning complement each other in limiting the ultimate migration distance of CO[subscript 2] gravity currents. The relative contribution of residual trapping, solubility trapping, and capillary pinning varies as a function of the injection volume. Our model can be used as a screening tool to evaluate the potential of deep saline aquifers for large-scale CO[subscript 2] sequestration.