Cooperative games defined by multi-objective optimization in competition for subsurface resources (2502.19987v1)

Abstract: We propose a novel decision making framework for forming potential collaboration among otherwise competing agents in subsurface systems. The agents can be, e.g., groundwater, CO$_2$, or hydrogen injectors and extractors with conflicting goals on a geophysically connected system. The operations of a given agent affect the other agents by induced pressure buildup that may jeopardize system integrity. In this work, such a situation is modeled as a cooperative game where the set of agents is partitioned into disjoint coalitions that define the collaborations. The games are in partition function form with externalities, i.e., the value of a coalition depends on both the coalition itself and on the actions of external agents. We investigate the class of cooperative games where the coalition values are the total injection volumes as given by Pareto optimal solutions to multi-objective optimization problems subject to arbitrary physical constraints. For this class of games, we prove that the Pareto set of any coalition structure is a subset of any other coalition structure obtained by splitting coalitions of the first coalition structure. Furthermore, the hierarchical structure of the Pareto sets is used to reduce the computational cost in an algorithm to hierarchically compute the entire Pareto fronts of all possible coalition structures. We demonstrate the framework on a pumping wells groundwater example, and nonlinear and realistic CO$_2$ injection cases, displaying a wide range of possible outcomes. Numerical cost reduction is demonstrated for the proposed algorithm with hierarchically computed Pareto fronts compared to independently solving the multi-objective optimization problems.