Entanglement in phase space

TL;DR

This paper explores the classical-quantum correspondence in phase space, analyzing entanglement, decoherence, and representations of quantum states through Wigner and chord functions, revealing how classical structures relate to quantum entanglement.

Contribution

It introduces a phase space perspective on quantum entanglement, connecting classical surfaces to quantum states and analyzing entanglement measures via Wigner and chord functions.

Findings

Entanglement corresponds to non-factorizable surfaces in phase space.

Reduced Wigner and chord functions quantify entanglement and partial trace effects.

Bell inequalities can be violated even with positive Wigner functions in classical evolution.

Abstract

Classical surfaces in phase space correspond to quantum states in Hilbert space. Subsystems specify factor spaces of the Hilbert space. An entangled state corresponds semiclassically to a surface that cannot be decomposed into a product of lower dimensional surfaces. Such a classical factorization never exists for ergodic eigenstates of a chaotic Hamiltonian. The space of quantum operators corresponds to a double phase space. The various representations of the density operator then result from alternative choices of allowed coordinate planes. In the case of the Wigner function and its Fourier transform, the chord function, or the quantum characteristic function, this is a phase space on its own. The reduced Wigner function, representing the partial trace of a density operator over a subsystem is the projection of the original Wigner function; the reduced chord function is obtained as a section. The purity of the reduced density operator, the square of its trace, is a measure of entanglement, obtained by integrating either the square of the reduced Wigner function, or the square-modulus of the reduced chord function. Bell inequalities for general parity measurements can be violated even for classical looking states with positive Wigner functions that have evolved classically from product states. These include the original EPR state. Entanglement with an unknown environment results in decoherence. An example is that of the centre of mass of a large number of independent particles, entangled with internal variables. In this case, the Central Limit Theorem for Wigner functions leads to some aspects of Markovian evolution for the reduced system.