We study the Hamiltonian structure of a vector–tensor theory with a non-minimal curvature coupling of the form ₄ X R, where X = A_ A^. Using a 3+1 ADM decomposition and Dirac’s constrained Hamiltonian formalism, we systematically analyze the kinetic structure of the theory and derive its full constraint algebra. The presence of the ₄ X R interaction induces kinetic mixing between the metric and vector sectors, leading to a non-trivial degeneracy in the Hessian matrix. This results in a branch-dependent constraint classification, where the nature of primary and secondary constraints depends on the rank structure of the kinetic operator. We identify the full set of primary constraints arising from null directions of the Hessian and study their time evolution to determine secondary constraints and consistency of the Dirac algorithm. The resulting phase-space structure shows that the number of propagating degrees of freedom is not fixed universally but depends on the degeneracy branch of the theory. Our results demonstrate that curvature-coupled vector–tensor theories generically exhibit non-trivial constraint embeddings, leading to modified gauge structures and branch-dependent Hamiltonian dynamics.
Rihab Tayar (Wed,) studied this question.