Related papers: Counterdiabatic-influenced Floquet-engineering: State preparation, annealing and learning the adiabatic gauge potential

Counterdiabatic-influenced Floquet-engineering: State preparation, annealing and learning the adiabatic gauge potential

URL: http://arxiv.org/abs/2501.14881v1
Date: Fri, 24 Jan 2025 19:13:59 GMT
Title: Counterdiabatic-influenced Floquet-engineering: State preparation, annealing and learning the adiabatic gauge potential
Authors: Callum W Duncan,
Abstract summary: We introduce a new technique for the control of quantum systems, Counterdiabatic-influenced Floquet-engineering or CAFFEINE. CAFFEINE parameterises the Floquet Hamiltonian for counterdiabatic driving and utilises numerical quantum optimal control in order to obtain the desired target state. We also illustrate CAFFEINE's capabilities to learn the counterdiabatic terms, which can potentially be used as a probe of quantum chaos and the geometry of quantum dynamics.
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Abstract: Counterdiabatic driving, which enforces adiabatic evolution in arbitrary timescales, can be realised by engineering a Floquet Hamiltonian which oscillates between the Hamiltonian and its derivative requiring no additional control terms. However, the coefficients of the Floquet Hamiltoinan require knowledge of the counterdiabatic terms, which can be difficult to derive outside of a limited set of examples. We introduce a new hybrid technique for the control of quantum systems, Counterdiabatic-influenced Floquet-engineering or CAFFEINE for short. CAFFEINE parameterises the Floquet Hamiltonian for counterdiabatic driving and utilises numerical quantum optimal control in order to obtain the desired target state. This removes the need to both obtain and implement counterdiabatic terms, however, it does require the ability to quickly oscillate each term in the Hamiltonian. If this oscillation is possible, then CAFFEINE provides a framework to implement quantum annealing protocols and general quantum state preparation. We illustrate this through optimisation of two numerical examples of preparing a Bell state with two qubits and performing annealing protocols for the one-dimensional Ising model. Beyond this, we also illustrate CAFFEINE's capabilities to learn the counterdiabatic terms, which can potentially be used as a probe of quantum chaos and the geometry of quantum dynamics.

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