Quantum contextuality in the Mermin-Peres square: A hidden variable perspective

TL;DR

This paper explores hidden variable interpretations of quantum contextuality in the Mermin-Peres square, proposing a model that accounts for measurement disturbance and challenges traditional notions of noncontextuality.

Contribution

It introduces a less restrictive definition of noncontextuality and constructs an explicit hidden variable model consistent with quantum predictions.

Findings

A hidden variable model reproduces all quantum predictions for the Mermin-Peres square.

Measurement disturbance can explain apparent contextuality.

Proposes a more reasonable definition of noncontextuality.

Abstract

The question of a hidden variable interpretation of quantum contextuality in the Mermin-Peres square is considered. The Kochen-Specker theorem implies that quantum mechanics may be interpreted as a contextual hidden variable theory. It is shown that such a hidden variable description can be viewed as either contextual in the random variables mapping hidden states to observable outcomes or in the probability measure on the hidden state space. The latter view suggests that this apparent contextuality may be interpreted as a simple consequence of measurement disturbance, wherein the initial hidden state is altered through interaction with the measuring device, thereby giving rise to a possibly different final hidden variable state from which the measurement outcome is obtained. In light of this observation, a less restrictive and, arguably, more reasonable definition of noncontextuality is suggested. To prove that such a description is possible, an explicit and, in this sense, noncontextual hidden variable model is constructed which reproduces all quantum theoretic predictions for the Mermin-Peres square. A critical analysis of some recent and proposed experimental tests of contextuality is also provided. Although the discussion is restricted to a four-dimensional Hilbert space, the approach and conclusions are expected to generalize to any Hilbert space.