An experimental investigation of measurement-induced disturbance and time symmetry in quantum physics

TL;DR

This paper experimentally investigates how even minimally disturbing weak measurements in quantum systems exhibit time-ordering dependence, challenging the notion of time symmetry in quantum measurement processes.

Contribution

It provides the first experimental evidence that weak measurements, despite low disturbance, still show time-ordering effects in quantum systems.

Findings

Weak measurements minimally disturb quantum states

Time-ordering affects measurement outcomes even with weak measurements

Results challenge assumptions about time symmetry in quantum measurement

Abstract

Unlike regular time evolution governed by the Schr\"odinger equation, standard quantum measurement appears to violate time-reversal symmetry. Measurement creates random disturbances (e.g., collapse) that prevents back-tracing the quantum state of the system. The effect of these disturbances is explicit in the results of subsequent measurements. In this way, the joint result of sequences of measurements depends on the order in time in which those measurements are performed. One might expect that if the disturbance could be eliminated this time-ordering dependence would vanish. Following a recent theoretical proposal [A. Bednorz et al 2013 New J. Phys. 15 023043], we experimentally investigate this dependence for a kind of measurement that creates an arbitrarily small disturbance, weak measurement. We perform various sequences of a set of polarization weak measurements on photons. We experimentally demonstrate that, although the weak measurements are minimally disturbing, their time-ordering affects the outcome of the measurement sequence for quantum systems.