Making Quantum Local Verifiers Simulable with Potential Applications to Zero-Knowledge

TL;DR

This paper advances quantum proof systems by showing local quantum verifiers can be made simulable, paving the way for zero-knowledge quantum arguments, with potential applications in quantum cryptography.

Contribution

It generalizes recent results to demonstrate that any local quantum verifier can be made simulable with minimal impact on soundness and completeness.

Findings

Local quantum verifiers can be made simulable

Simulability enables potential zero-knowledge properties

Progress towards zero-knowledge quantum proofs

Abstract

Recently Chen and Movassagh proposed the quantum Merkle tree, which is a quantum analogue of the well-known classical Merkle tree. It gives a succinct verification protocol for quantum state commitment. Although they only proved security against semi-honest provers, they conjectured its general security. Using the proposed quantum Merkle tree, they gave a quantum analogue of Kilian's succinct argument for NP, which is based on probabilistically checkable proofs (PCPs). A nice feature of Kilian's argument is that it can be extended to a zero-knowledge succinct argument for NP, if the underlying PCP is zero-knowledge. Hence, a natural question is whether one can also make the quantum succinct argument by Chen and Movassagh zero-knowledge as well. This work makes progress on this problem. We generalize the recent result of Broadbent and Grilo to show that any local quantum verifier can be made simulable with a minor reduction in completeness and soundness. Roughly speaking, a local quantum verifier is simulable if in the yes case, the local views of the verifier can be computed without knowing the actual quantum proof; it can be seen as the quantum analogue of the classical zero-knowledge PCPs. Hence we conjecture that applying the proposed succinct quantum argument of Chen and Movassagh to a simulable local verifier is indeed zero-knowledge.