Quantum Walks: Schur Functions Meet Symmetry Protected Topological Phases

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Standard

Quantum Walks : Schur Functions Meet Symmetry Protected Topological Phases. / Cedzich, C.; Geib, T.; Grünbaum, F. A.; Velázquez, L.; Werner, A. H.; Werner, R. F.

In: Communications in Mathematical Physics, Vol. 389, 2022, p. 31–74.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Cedzich, C, Geib, T, Grünbaum, FA, Velázquez, L, Werner, AH & Werner, RF 2022, 'Quantum Walks: Schur Functions Meet Symmetry Protected Topological Phases', Communications in Mathematical Physics, vol. 389, pp. 31–74. https://doi.org/10.1007/s00220-021-04284-8

APA

Cedzich, C., Geib, T., Grünbaum, F. A., Velázquez, L., Werner, A. H., & Werner, R. F. (2022). Quantum Walks: Schur Functions Meet Symmetry Protected Topological Phases. Communications in Mathematical Physics, 389, 31–74. https://doi.org/10.1007/s00220-021-04284-8

Vancouver

Cedzich C, Geib T, Grünbaum FA, Velázquez L, Werner AH, Werner RF. Quantum Walks: Schur Functions Meet Symmetry Protected Topological Phases. Communications in Mathematical Physics. 2022;389:31–74. https://doi.org/10.1007/s00220-021-04284-8

Author

Cedzich, C. ; Geib, T. ; Grünbaum, F. A. ; Velázquez, L. ; Werner, A. H. ; Werner, R. F. / Quantum Walks : Schur Functions Meet Symmetry Protected Topological Phases. In: Communications in Mathematical Physics. 2022 ; Vol. 389. pp. 31–74.

Bibtex

@article{cbf1a41cfe194d818f1eec3db0fa1c28,
title = "Quantum Walks: Schur Functions Meet Symmetry Protected Topological Phases",
abstract = "This paper uncovers and exploits a link between a central object in harmonic analysis, the so-called Schur functions, and the very hot topic of symmetry protected topological phases of quantum matter. This connection is found in the setting of quantum walks, i.e. quantum analogs of classical random walks. We prove that topological indices classifying symmetry protected topological phases of quantum walks are encoded by matrix Schur functions built out of the walk. This main result of the paper reduces the calculation of these topological indices to a linear algebra problem: calculating symmetry indices of finite-dimensional unitaries obtained by evaluating such matrix Schur functions at the symmetry protected points ± 1. The Schur representation fully covers the complete set of symmetry indices for 1D quantum walks with a group of symmetries realizing any of the symmetry types of the tenfold way. The main advantage of the Schur approach is its validity in the absence of translation invariance, which allows us to go beyond standard Fourier methods, leading to the complete classification of non-translation invariant phases for typical examples.",
author = "C. Cedzich and T. Geib and Gr{\"u}nbaum, {F. A.} and L. Vel{\'a}zquez and Werner, {A. H.} and Werner, {R. F.}",
note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",
year = "2022",
doi = "10.1007/s00220-021-04284-8",
language = "English",
volume = "389",
pages = "31–74",
journal = "Communications in Mathematical Physics",
issn = "0010-3616",
publisher = "Springer",

}

RIS

TY - JOUR

T1 - Quantum Walks

T2 - Schur Functions Meet Symmetry Protected Topological Phases

AU - Cedzich, C.

AU - Geib, T.

AU - Grünbaum, F. A.

AU - Velázquez, L.

AU - Werner, A. H.

AU - Werner, R. F.

N1 - Publisher Copyright: © 2021, The Author(s).

PY - 2022

Y1 - 2022

N2 - This paper uncovers and exploits a link between a central object in harmonic analysis, the so-called Schur functions, and the very hot topic of symmetry protected topological phases of quantum matter. This connection is found in the setting of quantum walks, i.e. quantum analogs of classical random walks. We prove that topological indices classifying symmetry protected topological phases of quantum walks are encoded by matrix Schur functions built out of the walk. This main result of the paper reduces the calculation of these topological indices to a linear algebra problem: calculating symmetry indices of finite-dimensional unitaries obtained by evaluating such matrix Schur functions at the symmetry protected points ± 1. The Schur representation fully covers the complete set of symmetry indices for 1D quantum walks with a group of symmetries realizing any of the symmetry types of the tenfold way. The main advantage of the Schur approach is its validity in the absence of translation invariance, which allows us to go beyond standard Fourier methods, leading to the complete classification of non-translation invariant phases for typical examples.

AB - This paper uncovers and exploits a link between a central object in harmonic analysis, the so-called Schur functions, and the very hot topic of symmetry protected topological phases of quantum matter. This connection is found in the setting of quantum walks, i.e. quantum analogs of classical random walks. We prove that topological indices classifying symmetry protected topological phases of quantum walks are encoded by matrix Schur functions built out of the walk. This main result of the paper reduces the calculation of these topological indices to a linear algebra problem: calculating symmetry indices of finite-dimensional unitaries obtained by evaluating such matrix Schur functions at the symmetry protected points ± 1. The Schur representation fully covers the complete set of symmetry indices for 1D quantum walks with a group of symmetries realizing any of the symmetry types of the tenfold way. The main advantage of the Schur approach is its validity in the absence of translation invariance, which allows us to go beyond standard Fourier methods, leading to the complete classification of non-translation invariant phases for typical examples.

UR - http://www.scopus.com/inward/record.url?scp=85122057478&partnerID=8YFLogxK

U2 - 10.1007/s00220-021-04284-8

DO - 10.1007/s00220-021-04284-8

M3 - Journal article

C2 - 35095108

AN - SCOPUS:85122057478

VL - 389

SP - 31

EP - 74

JO - Communications in Mathematical Physics

JF - Communications in Mathematical Physics

SN - 0010-3616

ER -

ID: 289460323