Litcius/Paper detail

Bridging Entanglement and Magic Resources within Operator Space

Neil Dowling, Kavan Modi, Gregory A. L. White

2025Physical Review Letters8 citationsDOI

Abstract

Local-operator entanglement (LOE) dictates the complexity of simulating Heisenberg evolution using tensor network methods, and it bears witness to many-body chaos for local dynamics. We show that LOE is also sensitive to how non-Clifford a unitary is-its magic resources. In particular, we prove that LOE is always upper-bound by three distinct magic monotones: T-count, unitary nullity, and operator-stabilizer Rényi entropy. Moreover, in the average case for large, random circuits, LOE and magic monotones approximately coincide. Our results imply that an operator evolution that is expensive to simulate using tensor network methods must also be inefficient using both stabilizer and Pauli truncation methods. In terms of a previous conjecture on the characteristic scaling of LOE, our results imply that nonintegrable spin chains cannot be simulated classically. Entanglement in operator space therefore measures a unified picture of nonclassical resources, in stark contrast to the Schrödinger picture.

Topics & Concepts

Quantum entanglementUnitary statePauli exclusion principlePauli matricesOperator (biology)Tensor productPhysicsTheoretical physicsConjectureBridging (networking)EmbeddingHilbert spaceQuantum mechanicsScalingUnitary operatorQubitEntanglement witnessTensor (intrinsic definition)MAGIC (telescope)MathematicsSpace (punctuation)Statistical physicsMagic squareSpin networkQuantum computerComputer scienceMultipartite entanglementSpin (aerodynamics)Operator spaceSquashed entanglementUnitary matrixPOVMQuantumTopology (electrical circuits)Pure mathematicsQuantum informationTime evolutionQuantum many-body systemsQuantum Computing Algorithms and ArchitectureTensor decomposition and applications