Conformal bridge transformation, $$ \mathcal{PT} $$- and supersymmetry

Inzunza, Luis; Plyushchay, Mikhail S.

doi:10.1007/jhep08(2022)228

Cited by 5 publications

(1 citation statement)

References 101 publications

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“…We believe that there are two main reasons. First, Krylov complexity can be applied to any quantum system making it computationally available, at least in principle, for a plethora of different cases including but not limited to condensed matter and many-body systems [13][14][15][16][17], quantum and conformal field theories [3][4][5][18][19][20], open systems [21][22][23][24][25], topological phases of matter [26,27] and many other topics related to aspects of the above and not only [28][29][30][31]. Second, it is related by its construction to inherent properties and characteristic parameters of the system, namely the Hamiltonian and the Hilbert space that it defines.…”

Section: Introductionmentioning

confidence: 99%

Krylov complexity in a natural basis for the Schrödinger algebra

Patramanis,

Sybesma

2024

SciPost Phys. Core

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We investigate operator growth in quantum systems with two-dimensional Schrödinger group symmetry by studying the Krylov complexity. While feasible for semisimple Lie algebras, cases such as the Schrödinger algebra which is characterized by a semi-direct sum structure are complicated. We propose to compute Krylov complexity for this algebra in a natural orthonormal basis, which produces a pentadiagonal structure of the time evolution operator, contrasting the usual tridiagonal Lanczos algorithm outcome. The resulting complexity behaves as expected. We advocate that this approach can provide insights to other non-semisimple algebras.

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Section: Introductionmentioning

confidence: 99%

Krylov complexity in a natural basis for the Schrödinger algebra

Patramanis,

Sybesma

2024

SciPost Phys. Core

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Weak-strong duality of the non-commutative Landau problem induced by a two-vortex permutation, and conformal bridge transformation

Alcala,

Plyushchay

2023

J. High Energ. Phys.

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A correspondence is established between the dynamics of the two-vortex system and the non-commutative Landau problem (NCLP) in its sub- (non-chiral), super- (chiral) and critical phases. As a result, a trivial permutation symmetry of the point vortices induces a weak-strong coupling duality in the NCLP. We show that quantum two-vortex systems with non-zero total vorticity can be generated by applying conformal bridge transformation to a two-dimensional quantum free particle or to a quantum vortex-antivortex system of zero total vorticity. The sub- and super-critical phases of the quantum NCLP are generated in a similar way from the 2D quantum free particle in a commutative or non-commutative plane. The composition of the inverse and direct transformations of the conformal bridge also makes it possible to link the non-chiral and chiral phases in each of these two systems.

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Integrability meets the charged relativistic particle

Correa,

López-Sarrión

2024

Physics Letters B

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Conformal bridge transformation, $$ \mathcal{PT} $$- and supersymmetry

Cited by 5 publications

References 101 publications

Krylov complexity in a natural basis for the Schrödinger algebra

Krylov complexity in a natural basis for the Schrödinger algebra

Weak-strong duality of the non-commutative Landau problem induced by a two-vortex permutation, and conformal bridge transformation

Integrability meets the charged relativistic particle

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