Quantum-classical dynamical brackets

We study the problem of constructing a general hybrid quantum-classical bracket from a partial classical limit of a full quantum bracket. Introducing a hybrid composition product, we show that such a bracket is the commutator of that product. From this we see that the hybrid bracket will obey the Jacobi identity and the Leibniz rule provided the composition product is associative. This suggests that the set of hybrid variables belonging to an associative subalgebra with the composition product will have consistent quantum-classical dynamics. This restricts the class of allowed quantum-classical interaction Hamiltonians. Furthermore, we show that pure quantum or classical variables can interact in a consistent framework, unaffected by no-go theorems in the literature or the restrictions for hybrid variables. In the proposed scheme, quantum backreaction appears as quantum-dependent terms in the classical equations of motion.

Automated summary

The study shows how to construct a general hybrid quantum-classical bracket and the rules it follows. It is demonstrated that the hybrid bracket will obey the Jacobi identity and the Leibniz rule, as long as the composition product is associative. The proposed scheme suggests that quantum backreaction manifests as quantum-dependent terms in classical equations of motion.