Catalytic quantum randomness

TL;DR

This paper explores the minimal quantum and classical randomness needed to transform quantum states, revealing a quadratic advantage of quantum sources and introducing robust, reusable protocols with applications in quantum information and thermodynamics.

Contribution

It provides provably optimal protocols for quantum and classical randomness sources, demonstrating a quadratic advantage of quantum coherence and introducing a robust, catalytic dephasing process.

Findings

Quantum randomness source of dimension √d suffices for noisy transitions

Quantum coherence offers a quadratic advantage over classical randomness

Protocols are robust and can be reused, enabling practical applications

Abstract

Randomness is a defining element of mixing processes in nature and an essential ingredient to many protocols in quantum information. In this work, we investigate how much randomness is required to transform a given quantum state into another one. Specifically, we ask whether there is a gap between the power of a classical source of randomness compared to that of a quantum one. We provide a complete answer to these questions, by identifying provably optimal protocols for both classical and quantum sources of randomness, based on a dephasing construction. We find that in order to implement any noisy transition on a $d$-dimensional quantum system it is necessary and sufficient to have a quantum source of randomness of dimension $\sqrt{d}$ or a classical one of dimension $d$. Interestingly, coherences provided by quantum states in a source of randomness offer a quadratic advantage. The process we construct has the additional features to be robust and catalytic, i.e., the source of randomness can be re-used. Building upon this formal framework, we illustrate that this dephasing construction can serve as a useful primitive in both equilibration and quantum information theory: We discuss applications describing the smallest measurement device, capturing the smallest equilibrating environment allowed by quantum mechanics, or forming the basis for a cryptographic private quantum channel. We complement the exact analysis with a discussion of approximate protocols based on quantum expanders deriving from discrete Weyl systems. This gives rise to equilibrating environments of remarkably small dimension. Our results highlight the curious feature of randomness that residual correlations and dimension can be traded against each other.