Summary: The declarative modeling language Alloy and its automatic analyzer provide an effective tool-set for building designs of systems and checking their properties. The Alloy Analyzer performs bounded exhaustive analysis using off-the-shelf SAT solvers. The analyzer’s performance hinges on the complexity of the models and so far, its feasibility has been shown only within limited bounds. We present a novel optimization technique that defines program slicing for declarative models and enables efficient analyses exploiting partial solutions. We present an algorithm that computes transient slices for Alloy models by partitioning them into a base and a derived slice. A satisfying solution to the base slice is systematically extended to generate a solution for the entire model, while unsatisfiability of the base implies unsatisfiability of the entire model. By generating slices, our approach enables constraint prioritization, where the base slice assumes higher priority than the derived slice. Compared to the complete model, base and derived slices represent smaller and, ideally, simpler sub-problems, which, in turn, enables efficient analyses for the underlying SAT solvers. Our approach analyzes the structure of a given model and constructs a set of candidate slicing criteria. Our prototype tool, Kato, performs a small-scope analysis for each criterion to determine whether declarative slicing optimization provides any performance gain and, if so, to select a criterion that is likely to provide an optimal performance enhancement. The experimental results show that, with declarative slicing, it is possible to achieve significant improvements compared to the Alloy Analyzer.