Long-range entanglement from measuring symmetry-protected topological phases

Tantivasadakarn, Nathanan; Thorngren, Ryan; Vishwanath, Ashvin; Verresen, Ruben

doi:10.48550/arxiv.2112.01519

Cited by 33 publications

(60 citation statements)

References 143 publications

(193 reference statements)

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“…Usually, gauging is a nonlocal transformation which would require a linear-depth circuit. However, in our companion work [52], we show that an arbitrary initial state can be gauged by a finite-depth circuit (made of controlled-Z gates) and single-site projections or measurements. Here we use this general fact to produce D4 topological order.…”

Section: Fracton Ordermentioning

confidence: 97%

“…At a conceptual level, this construction can be interpreted as effectively gauging the Z 2 charge-conjugation symmetry of the Z 3 toric code, in line with S 3 = Z 3 Z 2 . In a companion work, we explore more generally how gauging can be implemented using finite-depth timeevolution and measurements [52].…”

Section: Non-abelian Defects and Anyonsmentioning

confidence: 99%

“…Moreover, the authors thank Ryan Thorngren for collaboration on the companion work Ref. [52]. DMRG simulations were performed using the TeNPy Library [57].…”

Section: Acknowledgmentsmentioning

confidence: 99%

“…Non-Abelian D 4 or S 3 topological order can be obtained by using a four-step protocol where one timeevolves and measures twice, creating the color code [51] or Z 3 toric code [31] as an intermediate state. This can be conceptually interpreted as sequentially gauging certain symmetries, thereby expanding the possible states of matter which can be efficiently prepared by finite-time evolution and measurement, the theoretical ramifications of which we explore further in a companion work [52].…”

mentioning

confidence: 99%

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Efficiently preparing Schrödinger's cat, fractons and non-Abelian topological order in quantum devices

Verresen¹,

Tantivasadakarn²,

Vishwanath³

2021

Preprint

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Section: Fracton Ordermentioning

confidence: 97%

Section: Non-abelian Defects and Anyonsmentioning

confidence: 99%

“…Moreover, the authors thank Ryan Thorngren for collaboration on the companion work Ref. [52]. DMRG simulations were performed using the TeNPy Library [57].…”

Section: Acknowledgmentsmentioning

confidence: 99%

mentioning

confidence: 99%

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Efficiently preparing Schrödinger's cat, fractons and non-Abelian topological order in quantum devices

Verresen¹,

Tantivasadakarn²,

Vishwanath³

2021

Preprint

Self Cite

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“…These so-called categorical symmetries have received widespread attention in recent years, e.g. [23][24][25][26][27][28][29][30][31][32]. In the case that these models are critical, their low-energy physics is described by a conformal field theory, in which these non-local symmetries are identified with the topological defects [33][34][35][36][37][38].…”

Section: Sec I | Introductionmentioning

confidence: 99%

Dualities in one-dimensional quantum lattice models: symmetric Hamiltonians and matrix product operator intertwiners

Lootens¹,

Delcamp²,

Ortíz³

et al. 2021

Preprint

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We present a systematic approach for generating duality transformations in quantum lattice models. Within our formalism, dualities are completely characterized by equivalent but distinct realizations of a given (possibly non-abelian and non-invertible) symmetry. These different realizations are encoded into fusion categories, and dualities are methodically generated by considering all Morita equivalent categories. The full set of symmetric operators can then be constructed from the categorical data. We construct explicit intertwiners, in the form of matrix product operators, that convert local symmetric operators of one realization into local symmetric operators of its dual. Concurrently, it maps local operators that transform non-trivially into non-local ones. This guarantees that the structure constants of the algebra of all symmetric operators are equal in both dual realizations. Families of dual Hamiltonians, possibly with long range interactions, are then designed by taking linear combinations of the corresponding symmetric operators. We illustrate this approach by establishing matrix product operator intertwiners for well-known dualities such as Kramers-Wannier and Jordan-Wigner, consider theories with two copies of the Ising category symmetry, and present an example with quantum group symmetries. Finally, we comment on generalizations to higher dimensions of this categorical approach to dualities.

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Model-Independent Learning of Quantum Phases of Matter with Quantum Convolutional Neural Networks

et al. 2023

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Quantum convolutional neural networks (QCNNs) have been introduced as classifiers for gapped quantum phases of matter. Here, we propose a model-independent protocol for training QCNNs to discover order parameters that are unchanged under phase-preserving perturbations. We initiate the training sequence with the fixed-point wavefunctions of the quantum phase and add translation-invariant noise that respects the symmetries of the system to mask the fixed-point structure on short length scales. We illustrate this approach by training the QCNN on phases protected by time-reversal symmetry in one dimension, and test it on several timereversal symmetric models exhibiting trivial, symmetry-breaking, and symmetry-protected topological order. The QCNN discovers a set of order parameters that identifies all three phases and accurately predicts the location of the phase boundary. The proposed protocol paves the way towards hardware-efficient training of quantum phase classifiers on a programmable quantum processor.

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Long-range entanglement from measuring symmetry-protected topological phases

Cited by 33 publications

References 143 publications

Efficiently preparing Schrödinger's cat, fractons and non-Abelian topological order in quantum devices

Efficiently preparing Schrödinger's cat, fractons and non-Abelian topological order in quantum devices

Dualities in one-dimensional quantum lattice models: symmetric Hamiltonians and matrix product operator intertwiners

Model-Independent Learning of Quantum Phases of Matter with Quantum Convolutional Neural Networks

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