Universal finite-size scaling around tricriticality between topologically ordered, symmetry-protected topological, and trivial phases

Wang, Ke; Sedrakyan, Tigran

doi:10.1103/physrevb.101.035410

Cited by 7 publications

(4 citation statements)

References 43 publications

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“…The estimated D c and ν values are also compatible with available data from the twisted boundary conditions method [25,32] and high-accuracy calculations based on large-scale DMRG studies using chains up to N = 10 4 sites [42]. Considering that the tangential finite-size scaling analysis requires data from relatively small chains sizes, it appears as a powerful procedure that adds to recent efforts aiming to investigate Gaussian topological quantum phase-transitions in general spin chains [52][53][54][55][56].…”

Section: Discussionsupporting

confidence: 77%

Tangential finite-size scaling of the Gaussian topological transition in the quantum spin-1 anisotropic chain

Veríssimo,

Pereira,

Lyra

2021

Preprint

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Scaling aspects of Gaussian topological phase-transitions in quantum spin chains are investigated using the prototypical one-dimensional spin-1 XXZ Heisenberg model with uniaxial single-ion anisotropy D. This model presents a critical line separating the gaped Haldane and large-D phases, with the relevant energy gap closing at the transition point. We show that a proper tangential finite-size scaling analysis is able to accurately locate the Gaussian critical line and to probe the continuously varying set of correlation length critical exponents. The specific features of the tangential scaling are highlighted in contrast with the standard scaling holding in the Ising-like transition between the gapless AF-Néel and gaped Haldane phases. Our results are compared with fieldtheoretic predictions and available high-accuracy data for specific points along the Gaussian line.

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Section: Discussionsupporting

confidence: 77%

Tangential finite-size scaling of the Gaussian topological transition in the quantum spin-1 anisotropic chain

Veríssimo,

Pereira,

Lyra

2021

Preprint

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“…These states, often with non-standard statistics, are substantial for the basics of topological quantum computation. The topological systems near criticality are generally remarkable for their universal finite-size scaling behavior [41,42] and sensitivity to symmetry-breaking perturbations [43,44]. They may possess both paramagnetic [9] and spin-ordered phases, with the latter being closely related to Neel orders [45][46][47].…”

Section: Introductionmentioning

confidence: 99%

$Z_3$ and $(\times Z_3)^3$ symmetry protected topological paramagnets

Topchyan¹,

Iugov²,

Mirumyan³

et al. 2022

Preprint

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We identify three-state Potts paramagnets with gapless edge modes on a triangular lattice protected by (×Z 3 ) 3 ≡ Z 3 × Z 3 × Z 3 symmetry and smaller Z 3 symmetry. We study microscopic models for the gapless edge and discuss the corresponding conformal field theories and their central charges. These are the edge states of s = 1 paramagnets protected by Z 3 ×Z 3 ×Z 3 and Z 3 symmetries, in analogy with the free fermion XX model edge discussed by Levin and Gu for the spin-1/2 Z 2 Ising paramagnet. We show that in spin-1 magnets, there are numerous options to obtain self-dual Hamiltonians and gapless edge modes. These models form the basis for the realization of a variety of symmetry-protected topological phases, opening a window for studies of the unconventional quantum criticalities between them.

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“…The magnitude of A is anomalously large as it is of the order of one. There exists rich phenomena in finite-size scaling functions around this criticality 10,[31][32][33] . For example, with Eq.…”

mentioning

confidence: 99%

“…This offers an opportunity to observe the effects of zero modes in the fermionic field theory [38][39][40] . Similarly, one can also explore the behaviors of entanglement entropy and boundary entropy 31,[42][43][44][45] around Π.…”

mentioning

confidence: 99%

Universal finite-size amplitude and anomalous entanglement entropy of $z=2$ quantum Lifshitz criticalities in topological chains

Wang,

Sedrakyan

2021

Preprint

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We consider Lifshitz criticalities with dynamical exponent z = 2 that emerge in a class of topological chains. There, such a criticality plays a fundamental role in describing transitions between symmetry-enriched conformal field theories (CFTs). We report that, at such critical points in one spatial dimension, the finite-size correction to the energy scales with system size, L, as ∼ L −2 , with universal and anomalously large coefficient. The behavior originates from the specific dispersion around the Fermi surface, ∝ ±k 2 . We also show that the entanglement entropy exhibits at the criticality a non-logarithmic dependence on l/L, where l is the length of the sub-system. In the limit of l L, the maximally-entangled ground state has the entropy, S(l/L) = S0 + (l/L) log(l/L). Here S0 is some non-universal entropy originating from short-range correlations. We show that the novel entanglement originates from the long-range correlation mediated by a zero mode in the low energy sector. The work paves the way to study finite-size effects and entanglement entropy around Lifshitz criticalities and offers an insight into transitions between symmetry-enriched criticalities.

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Universal finite-size scaling around tricriticality between topologically ordered, symmetry-protected topological, and trivial phases

Cited by 7 publications

References 43 publications

Tangential finite-size scaling of the Gaussian topological transition in the quantum spin-1 anisotropic chain

Tangential finite-size scaling of the Gaussian topological transition in the quantum spin-1 anisotropic chain

$Z_3$ and $(\times Z_3)^3$ symmetry protected topological paramagnets

Universal finite-size amplitude and anomalous entanglement entropy of $z=2$ quantum Lifshitz criticalities in topological chains

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