What question did this study set out to answer?

The aim is to define and quantify chirality in quantum states and explore its connections to quantum resources.

March 4, 2026Open Access

Chirality, magic, and quantum correlations in multipartite quantum states

Key Points

The aim is to define and quantify chirality in quantum states and explore its connections to quantum resources.
Introduced a definition of chirality based on transformations under local unitary operations.
Developed several quantitative measures of chirality, including the chiral log-distance.
Utilized nested commutators of modular Hamiltonians to establish chirality measures.
Found that qubit stabilizer states are always non-chiral.
Demonstrated that the chiral log-distance provides lower bounds for multiple magic monotones.
Showed that a nested commutator-based chirality measure is lower bounded by a type of interferometric power.

Abstract

Chirality is a fundamental property of many topological phases, yet it lacks a general information-theoretic formulation. In this work, we introduce a notion of chirality for generic quantum states, defined by the impossibility of transforming a state into its complex conjugate under local unitary operations. We propose several quantitative measures of chirality, including a faithful metric called the chiral log-distance, and a family of nested commutators of modular Hamiltonians. We show that chirality, although not a resource in the traditional sense, is intrinsically linked to two major classes of quantum resources: magic and quantum correlations. In particular, we demonstrate that (i) qubit stabilizer states are always non-chiral, (ii) the chiral log-distance provides a lower bound for several magic monotones, and (iii) a nested commutator-based chirality measure is lower bounded by a variant of interferometric power.

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