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Measurement as a Shortcut to Long-Range Entangled Quantum Matter

Tsung-Cheng Lu, Leonardo A. Lessa, Isaac H. Kim, Timothy H. Hsieh

2022PRX Quantum129 citationsDOIOpen Access PDF

Abstract

The preparation of long-range entangled states using unitary circuits is limited by Lieb-Robinson bounds, but circuits with projective measurements and feedback ("adaptive circuits") can evade such restrictions. We introduce three classes of local adaptive circuits that enable low-depth preparation of long-range entangled quantum matter characterized by gapped topological orders and conformal field theories (CFTs). The three classes are inspired by distinct physical insights, including tensor-network constructions, the multiscale entanglement renormalization ansatz, and parton constructions. A large class of topological orders, including chiral topological order, can be prepared in constant depth or time, and onedimensional CFT states and non-Abelian topological orders with both solvable and nonsolvable groups can be prepared in depth scaling logarithmically with system size. We also build on a recently discovered correspondence between symmetry-protected topological phases and long-range entanglement to derive efficient protocols for preparing symmetry-enriched topological order and arbitrary Calderbank-Shor-Steane codes. Our work illustrates the practical and conceptual versatility of measurement for state preparation.

Topics & Concepts

Quantum entanglementAnsatzTopology (electrical circuits)PhysicsToric codeTopological orderRenormalizationUnitary stateAbelian groupTheoretical physicsQuantumQuantum mechanicsMathematicsPure mathematicsCombinatoricsLawPolitical scienceQuantum many-body systemsQuantum and electron transport phenomenaQuantum Computing Algorithms and Architecture