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Auteur principal: Duncan, Callum W.
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2403.12150
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_version_ 1866929281537409024
author Duncan, Callum W.
author_facet Duncan, Callum W.
contents Adiabatic protocols are often employed in state preparation schemes but require the system to be driven by a slowly varying Hamiltonian so that transitions between instantaneous eigenstates are exponentially suppressed. Counterdiabatic driving is a technique to speed up adiabatic protocols by including additional terms calculated from the instantaneous eigenstates that counter diabatic excitations. However, this approach requires knowledge of the full eigenspectrum meaning that the exact analytical form of counterdiabatic driving is only known for a subset of problems, e.g., the harmonic oscillator and transverse field Ising model. We extend this subset of problems to include the general family of one-dimensional non-interacting lattice models with open boundary conditions and arbitrary on-site potential, tunnelling terms, and lattice size. We formulate this approach for all states of lattice models, including bound and in-gap states which appear, e.g., in topological insulators. We also derive targeted counterdiabatic driving terms which are tailored to enforce the dynamical state to remain in a specific state. As an example, we consider state transfer using the topological edge states of the Su-Schrieffer-Heeger model. The derived analytical counterdiabatic driving Hamiltonian can be utilised to inform control protocols in many-body lattice models or to probe the non-equilibrium properties of lattice models.
format Preprint
id arxiv_https___arxiv_org_abs_2403_12150
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Exact counterdiabatic driving for finite topological lattice models
Duncan, Callum W.
Quantum Physics
Strongly Correlated Electrons
Adiabatic protocols are often employed in state preparation schemes but require the system to be driven by a slowly varying Hamiltonian so that transitions between instantaneous eigenstates are exponentially suppressed. Counterdiabatic driving is a technique to speed up adiabatic protocols by including additional terms calculated from the instantaneous eigenstates that counter diabatic excitations. However, this approach requires knowledge of the full eigenspectrum meaning that the exact analytical form of counterdiabatic driving is only known for a subset of problems, e.g., the harmonic oscillator and transverse field Ising model. We extend this subset of problems to include the general family of one-dimensional non-interacting lattice models with open boundary conditions and arbitrary on-site potential, tunnelling terms, and lattice size. We formulate this approach for all states of lattice models, including bound and in-gap states which appear, e.g., in topological insulators. We also derive targeted counterdiabatic driving terms which are tailored to enforce the dynamical state to remain in a specific state. As an example, we consider state transfer using the topological edge states of the Su-Schrieffer-Heeger model. The derived analytical counterdiabatic driving Hamiltonian can be utilised to inform control protocols in many-body lattice models or to probe the non-equilibrium properties of lattice models.
title Exact counterdiabatic driving for finite topological lattice models
topic Quantum Physics
Strongly Correlated Electrons
url https://arxiv.org/abs/2403.12150