Algebraic Bethe Circuits

Sopena, Alejandro; Gordon, Max Hunter; Sierra, Germȧn; López, Esperanza

doi:10.22331/q-2022-09-08-796

Cited by 15 publications

(16 citation statements)

References 70 publications

(134 reference statements)

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“…In that case, Ĥ0 can be simulated using a constant depth circuit. Similar cases of known implementations of Ĥ0 are 1D XY-models [28], Bethe diagonalizable models [71], and translational invariant models [34].…”

Section: Supplementary Materials For "Large-scale Simulations Of Floq...mentioning

confidence: 90%

“…The transversely driven Ising model (independent of topology and dimension) falls into this category. More generally, one could use known methods for simulating the time-independent 1D XY -model [28], Bethe diagonalizable models [71] and translationally symmetric models [34], to simulate the effect of local driving on such systems. We note that in classical simulations of Floquet systems, high frequency expansions are known and commonly used [63,[65][66][67][68] both for simulation and for Floquet engineering.…”

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confidence: 99%

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Large-scale simulations of Floquet physics on near-term quantum computers

Eckstein¹,

Mansuroglu²,

Czarnik³

et al. 2023

Preprint

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Quantum systems subject to periodic driving exhibit a diverse set of phenomena both of fundamental and technological interest. However, such dynamical systems are more challenging to simulate classically than their equilibrium counterparts. Here, we introduce the Quantum High Frequency Floquet Simulation (QHiFFS) algorithm as a method for simulating the dynamics of fast-driven Floquet systems on quantum hardware. Central to QHiFFS is the concept of a kick operator which transforms the system into a basis where the dynamics is governed by a time-independent effective Hamiltonian. This allows prior methods for time-independent Hamiltonian simulation to be lifted to the simulation of Floquet systems. We use the periodically driven biaxial next-nearest neighbor Ising (BNNNI) model as a case study to illustrate our algorithm. This oft-studied model is a natural test bed for quantum frustrated magnetism and criticality. We successfully implemented a 20-qubit simulation of the driven two-dimensional BNNNI model on Quantinuum's trapped ion quantum computer. This is complemented with an analysis of QHiFFS algorithmic errors. Our study indicates that the algorithm exhibits not only a cubic scaling advantage in driving frequency ω but also a linear one in simulation time t compared to Trotterisation, making it an interesting avenue to push towards near-term quantum advantage.

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Section: Supplementary Materials For "Large-scale Simulations Of Floq...mentioning

confidence: 90%

mentioning

confidence: 99%

Large-scale simulations of Floquet physics on near-term quantum computers

Eckstein¹,

Mansuroglu²,

Czarnik³

et al. 2023

Preprint

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show abstract

“…The quantum gates of Figure 3 ultimately follow from a recurrence relation. The recurrence is involved, and [15] provided analytical expressions for M = 1, 2, whereas it computed the quantum gates numerically for M > 2. This problem served as a starting point for [16], which obtained closed formulae for the quantum gates of the ABC.…”

Section: The Algebraic Bethe Circuitmentioning

confidence: 99%

“…Reference [15] alternatively developed a deterministic quantum algorithm, called algebraic Bethe circuit (ABC), that prepares Bethe states based on the ABA. The number of qubits and quantum gates scale polynomially with N .…”

Section: Introductionmentioning

confidence: 99%

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The Bethe Ansatz as a Quantum Circuit

Ruiz,

Sopena,

Gordon

et al. 2023

J. Phys.: Conf. Ser.

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The Bethe ansatz is an analytical method to solve exactly solvable models in quantum mechanics. It has been shown that the states of the Bethe ansatz can be prepared by a deterministic quantum circuit whose quantum gates were determined numerically. We report our progress in recasting the Bethe ansatz as a deterministic quantum circuit. We present the analytical expressions of the quantum gates. Formulae rely upon diagrammatic rules that define the wave functions of the Bethe ansatz by matrix product states. Based on the analytical expressions, we prove the unitarity of the quantum gates. We use our results to clarify on the equivalence between the coordinate and algebraic Bethe ansatze in light of matrix-product states.

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