Litcius/Paper detail

Nishimori’s Cat: Stable Long-Range Entanglement from Finite-Depth Unitaries and Weak Measurements

Guoyi Zhu, Nathanan Tantivasadakarn, Ashvin Vishwanath, Simon Trebst, Ruben Verresen

2023Physical Review Letters102 citationsDOI

Abstract

In the field of monitored quantum circuits, it has remained an open question whether finite-time protocols for preparing long-range entangled states lead to phases of matter that are stable to gate imperfections, that can convert projective into weak measurements. Here, we show that in certain cases, long-range entanglement persists in the presence of weak measurements, and gives rise to novel forms of quantum criticality. We demonstrate this explicitly for preparing the two-dimensional Greenberger-Horne-Zeilinger cat state and the three-dimensional toric code as minimal instances. In contrast to random monitored circuits, our circuit of gates and measurements is deterministic; the only randomness is in the measurement outcomes. We show how the randomness in these weak measurements allows us to track the solvable Nishimori line of the random-bond Ising model, rigorously establishing the stability of the glassy long-range entangled states in two and three spatial dimensions. Away from this exactly solvable construction, we use hybrid tensor network and Monte Carlo simulations to obtain a nonzero Edwards-Anderson order parameter as an indicator of long-range entanglement in the two-dimensional scenario. We argue that our protocol admits a natural implementation in existing quantum computing architectures, requiring only a depth-3 circuit on IBM's heavy-hexagon transmon chips.

Topics & Concepts

Quantum entanglementRandomnessPhysicsIsing modelStatistical physicsQuantum computerQuantum circuitQuantum decoherenceQuantum mechanicsQuantumTopology (electrical circuits)Quantum networkMathematicsStatisticsCombinatoricsQuantum many-body systemsQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomena