Certifying asymmetry in the configuration of three qubits

TL;DR

This paper introduces a method to certify asymmetry in the configuration of three unknown qubit states using a linear witness, demonstrating its effectiveness both numerically and experimentally on a quantum processor.

Contribution

It develops a novel linear witness approach to certify asymmetry in three-qubit configurations and experimentally verifies it on a quantum processor.

Findings

Successfully certifies asymmetry in qubit configurations experimentally.

Derives bounds for mirror-symmetric configurations to identify asymmetry.

Shows the most asymmetric configuration forms a right scalene triangle on the Bloch sphere.

Abstract

Symmetry restrictions limit the types of tasks that can be achieved with a given set of quantum states. Therefore, any breaking of these symmetries could potentially be exploited as a resource for quantum communication. Here we demonstrate this operationally by certifying asymmetry in the configuration of the Bloch vectors of a set of three unknown qubit states within the dimensionally bounded prepare-and-measure scenario. To do this, we construct a linear witness from three simpler witnesses as building blocks, each featuring, along with two binary measurement settings, three preparations; two of them are associated with the certification task, while the third one serves as an auxiliary. The final witness is chosen to self-test some target configuration. We numerically derive a bound $Q_{\text{mirror}}$ for any mirror-symmetric configuration, thereby certifying asymmetry if this bound is exceeded (e.g. experimentally) for the unknown qubit configuration. We also consider the gap $(Q_{\text{max}}-Q_{\text{mirror}})$ between the analytically derived overall quantum maximum $Q_{\text{max}}$ and the mirror-symmetric bound, and use it as a quantifier of asymmetry in the target configuration. Numerical optimization shows that the most asymmetric configuration then forms a right scalene triangle on the unit Bloch sphere. Finally, we implement our protocol on a public quantum processor, where a clear violation of the mirror-symmetric bound certifies asymmetry in the configuration of our experimental triple of qubit states.