Entanglement-free Heisenberg-limited phase estimation

TL;DR

This paper demonstrates a method for achieving Heisenberg-limited phase estimation without entangled states by using multiple applications of phase shifts on unentangled single photons, significantly improving measurement precision.

Contribution

The authors experimentally realize Heisenberg-limited phase estimation using unentangled photons and adaptive measurement, avoiding complex entangled states.

Findings

Achieved phase variance more than 10 dB below standard quantum limit at N=378

Demonstrated Heisenberg-limited scaling with unentangled photons

Reduced complexity of quantum-enhanced measurement techniques

Abstract

Measurement underpins all quantitative science. A key example is the measurement of optical phase, used in length metrology and many other applications. Advances in precision measurement have consistently led to important scientific discoveries. At the fundamental level, measurement precision is limited by the number N of quantum resources (such as photons) that are used. Standard measurement schemes, using each resource independently, lead to a phase uncertainty that scales as 1/sqrt(N) - known as the standard quantum limit. However, it has long been conjectured that it should be possible to achieve a precision limited only by the Heisenberg uncertainty principle, dramatically improving the scaling to 1/N. It is commonly thought that achieving this improvement requires the use of exotic quantum entangled states, such as the NOON state. These states are extremely difficult to generate. Measurement schemes with counted photons or ions have been performed with N <= 6, but few have surpassed the standard quantum limit and none have shown Heisenberg-limited scaling. Here we demonstrate experimentally a Heisenberg-limited phase estimation procedure. We replace entangled input states with multiple applications of the phase shift on unentangled single-photon states. We generalize Kitaev's phase estimation algorithm using adaptive measurement theory to achieve a standard deviation scaling at the Heisenberg limit. For the largest number of resources used (N = 378), we estimate an unknown phase with a variance more than 10 dB below the standard quantum limit; achieving this variance would require more than 4,000 resources using standard interferometry. Our results represent a drastic reduction in the complexity of achieving quantum-enhanced measurement precision.