Subsystem symmetry enriched topological order in three dimensions

Stephen, David T.; Garre-Rubio, José; Dua, Arpit; Williamson, Dominic J.

doi:10.1103/physrevresearch.2.033331

Cited by 34 publications

(24 citation statements)

References 85 publications

(200 reference statements)

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“…Second, the origin of LRE under measurement is tied to a specific anomaly involving the symmetries-related to the anomaly living at the boundary of the original SPT phase-thereby constraining the nature of the resulting LRE. Third, this allows for the preparation of states that are not realized by stabilizer codes, such as topological order described by twisted gauge theories or non-Abelian fracton orders [60][61][62][63][64][65][66][67][68][69]. Fourth, we achieve a new perspective on Kramers-Wannier (KW) [18,[70][71][72][73][74][75][76][77] and Jordan-Wigner (JW) [78][79][80][81][82][83][84][85][86] transformations.…”

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confidence: 99%

“…Note that this already contains certain non-Abelian phases, e.g., D 4 topological order arises upon gauging the Z 3 2 symmetry of an SPT phase with type-III cocycle [96,97]. (For obtaining non-Abelian topological order associated to any solvable group, see Section III C.) Similarly, our procedure allows for the creation of twisted fracton phases by gauging 3D subsystem SPT phases [65,83,84,98,99]. Thus a much wider class of states can be obtained from local unitary circuits and LOCC (local operations and classical communications) [54] than previously established.…”

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confidence: 99%

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Long-range entanglement from measuring symmetry-protected topological phases

Tantivasadakarn¹,

Thorngren²,

Vishwanath³

et al. 2021

Preprint

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A fundamental distinction between many-body quantum states are those with short-and longrange entanglement (SRE and LRE). The latter cannot be created by finite-depth circuits, underscoring the nonlocal nature of Schrödinger cat states, topological order, and quantum criticality.Remarkably, examples are known where LRE is obtained by performing single-site measurements on SRE, such as the toric code from measuring a sublattice of a 2D cluster state. However, a systematic understanding of when and how measurements of SRE give rise to LRE is still lacking. Here we establish that LRE appears upon performing measurements on symmetry protected topological (SPT) phases-of which the cluster state is one example. For instance, we show how to implement the Kramers-Wannier transformation, by adding a cluster SPT to an input state followed by measurement. This transformation naturally relates states with SRE and LRE. An application is the realization of double-semion order when the input state is the Z2 Levin-Gu SPT. Similarly, the addition of fermionic SPTs and measurement leads to an implementation of the Jordan-Wigner transformation of a general state. More generally, we argue that a large class of SPT phases protected by G×H symmetry gives rise to anomalous LRE upon measuring G-charges. This introduces a new practical tool for using SPT phases as resources for creating LRE, and uncovers the classification result that all states related by sequentially gauging Abelian groups or by Jordan-Wigner transformation are in the same equivalence class, once we augment finite-depth circuits with singlesite measurements. In particular, any topological or fracton order with a solvable finite gauge group can be obtained from a product state in this way.

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confidence: 99%

mentioning

confidence: 99%

Long-range entanglement from measuring symmetry-protected topological phases

Tantivasadakarn¹,

Thorngren²,

Vishwanath³

et al. 2021

Preprint

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“…In two dimensions, we expect that all nontrivial bifurcating symmetric ERG flows in gapped phases originate due to SSPTs. This is because in 2D only conventional topological phases, which contain unique fixed points, are possible [36,37], and there are no nontrivial SSET phases beyond stacking an SSPT with a decoupled topological order [63]. We remark that in three or higher dimensions, it is possible to have nontrivial gapped fracton topological phases that contain bifurcating ERG fixed points [30][31][32].…”

Section: Twist Phases and Classification Of Ssptsmentioning

confidence: 88%

“…We remark that in three or higher dimensions, it is possible to have nontrivial gapped fracton topological phases that contain bifurcating ERG fixed points [30][31][32]. It is also possible to enrich conventional topological phases to form nontrivial SSET phases [63]. While we have focused on the simplest nontrivial setting of two-dimensional phases in this paper, the bifurcating ERG of subsystem symmetry-enriched phases presents an interesting avenue for future study.…”

Section: Twist Phases and Classification Of Ssptsmentioning

confidence: 96%

Bifurcating subsystem symmetric entanglement renormalization in two dimensions

2021

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We introduce the subsystem symmetry-preserving real-space entanglement renormalization group and apply it to study bifurcating flows generated by linear and fractal subsystem symmetry-protected topological phases in two spatial dimensions. We classify all bifurcating fixed points that are given by subsystem symmetric cluster states with two qubits per unit cell. In particular, we find that the square lattice cluster state is a quotient-bifurcating fixed point, while the cluster states derived from Yoshida's first-order fractal spin liquid models are self-bifurcating fixed points. We discuss the relevance of bifurcating subsystem symmetry-preserving renormalization group fixed points for the classification and equivalence of subsystem symmetry-protected topological phases.

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“…In this general setting, it is generally not possible to gauge the full non-Abelian subsystem symmetry group; only an Abelian subgroup of the symmetry group can be gauged, thus giving rise to an Abelian fracton order 1 . Other examples of non-Abelian fracton orders have been recently proposed, by strongly coupling nonabelian topological orders in 2D and 3D [20][21][22][23][24][25], by gauging the abelian subsystem symmetries in certain symmetryprotected topological phases [26,27], or gauging a global symmetry which permutes fracton excitations in an abelian 1 Suppose the system of interest has three intersecting planar symmetries, each of which transforms a given plane under a non-abelian group G. The group commutator of two intersecting planar symmetries acts only on the intersection line. Therefore, the system has additional line symmetries given by the commutator subgroup [G, G].…”

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confidence: 99%

Non-Abelian Hybrid Fracton Orders

Tantivasadakarn,

Ji,

Vijay

2021

Preprint

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We introduce lattice gauge theories which describe three-dimensional, gapped quantum phases exhibiting the phenomenology of both conventional three-dimensional topological orders and fracton orders, starting from a finite group G, a choice of an Abelian normal subgroup N , and a choice of foliation structure. These hybrid fracton orders -examples of which were introduced in Ref.[1] -can also host immobile, point-like excitations that are non-Abelian, and therefore give rise to a protected degeneracy. We construct solvable lattice models for these orders which interpolate between a conventional, three-dimensional G gauge theory and a pure fracton order, by varying the choice of normal subgroup N . We demonstrate that certain universal data of the topological excitations and their mobilities are directly related to the choice of G and N , and also present complementary perspectives on these orders: certain orders may be obtained by gauging a global symmetry which enriches a particular fracton order, by either fractionalizing on or permuting the excitations with restricted mobility, while certain hybrid orders can be obtained by condensing excitations in a stack of initially decoupled, twodimensional topological orders.

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Subsystem symmetry enriched topological order in three dimensions

Cited by 34 publications

References 85 publications

Long-range entanglement from measuring symmetry-protected topological phases

Long-range entanglement from measuring symmetry-protected topological phases

Bifurcating subsystem symmetric entanglement renormalization in two dimensions

Non-Abelian Hybrid Fracton Orders

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