Simulating spectroscopy experiments with a superconducting quantum computer

We present a novel method for solving eigenvalue problems on a quantum computer based on spectroscopy. The method works by coupling a "probe" qubit to a set of system simulation qubits and then time evolving both the probe and the system under Hamiltonian dynamics. In this way, we simulate...

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Veröffentlicht in:	arXiv.org 2023-02
Hauptverfasser:	Stenger, John P T, Ben-Shach, Gilad, Pekker, David, Bronn, Nicholas T
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Electrons Hamiltonian functions Physics - Materials Science Physics - Quantum Physics Quantum computers Quantum computing Qubits (quantum computing) Spectroscopy
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description	We present a novel method for solving eigenvalue problems on a quantum computer based on spectroscopy. The method works by coupling a "probe" qubit to a set of system simulation qubits and then time evolving both the probe and the system under Hamiltonian dynamics. In this way, we simulate spectroscopy on a quantum computer. We test our method on the IBM quantum hardware for a simple single spin model and an interacting Kitaev chain model. For the Kitaev chain, we trace out the pseudo-topological phase boundary for a two-site model.
doi_str_mv	10.48550/arxiv.2202.12910
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subjects	Algorithms Electrons Hamiltonian functions Physics - Materials Science Physics - Quantum Physics Quantum computers Quantum computing Qubits (quantum computing) Spectroscopy
title	Simulating spectroscopy experiments with a superconducting quantum computer
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