Geometric representations of braid and Yang–Baxter gates

Zhang, Kun; Hao, Kun; Yu, Kwangmin; Korepin, Vladimir; Yang, Wen-Li

doi:10.1088/1751-8121/ad85b2

J. Phys. A: Math. Theor.

2024

DOI: 10.1088/1751-8121/ad85b2

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Geometric representations of braid and Yang–Baxter gates

Kun Zhang,

Kun Hao,

Kwangmin Yu

et al.

Abstract: Brick-wall circuits composed of the Yang-Baxter gates are integrable. It becomes an important tool to study the quantum many-body system out of equilibrium. To put the Yang-Baxter gate on quantum computers, it has to be decomposed into the native gates of quantum computers. It is favorable to apply the least number of native two-qubit gates to construct the Yang-Baxter gate. We study the geometric representations of all X-type braid gates and their corresponding Yang-Baxter gates via the Yang-Baxterization. We… Show more

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Algebraic classification of Hietarinta’s solutions of Yang-Baxter equations: invertible 4 × 4 operators

Maity,

Singh,

Padmanabhan

et al. 2024

J. High Energ. Phys.

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In order to examine the simulation of integrable quantum systems using quantum computers, it is crucial to first classify Yang-Baxter operators. Hietarinta was among the first to classify constant Yang-Baxter solutions for a two-dimensional local Hilbert space (qubit representation). Including the one produced by the permutation operator, he was able to construct eleven families of invertible solutions. These techniques are effective for 4 by 4 solutions, but they become difficult to use for representations with more dimensions. To get over this limitation, we use algebraic ansätze to generate the constant Yang-Baxter solutions in a representation independent way. We employ four distinct algebraic structures that, depending on the qubit representation, replicate 10 of the 11 Hietarinta families. Among the techniques are partition algebras, Clifford algebras, Temperley-Lieb algebras, and a collection of commuting operators. Using these techniques, we do not obtain the (2, 2) Hietarinta class.

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Algebraic classification of Hietarinta’s solutions of Yang-Baxter equations: invertible 4 × 4 operators

Maity,

Singh,

Padmanabhan

et al. 2024

J. High Energ. Phys.

View full text Add to dashboard Cite

show abstract

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Geometric representations of braid and Yang–Baxter gates

Cited by 1 publication

References 69 publications

Algebraic classification of Hietarinta’s solutions of Yang-Baxter equations: invertible 4 × 4 operators

Algebraic classification of Hietarinta’s solutions of Yang-Baxter equations: invertible 4 × 4 operators

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