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Quantum algorithm for solving open-system dynamics on quantum computers using noise

Juha Leppäkangas, Nicolas Vogt, Keith R. Fratus, Kirsten Bark, Jesse A. Vaitkus, Pascal Stadler, Jan-Michael Reiner, Sebastian Zanker, Michael Marthaler

2023Physical review. A/Physical review, A22 citationsDOI

Abstract

In this paper we present a quantum algorithm that uses noise as a resource. The goal of our quantum algorithm is the calculation of operator averages of an open quantum system evolving in time. Selected low-noise system qubits and noisy bath qubits represent the system and the bath of the open quantum system. All incoherent qubit noise can be mapped to bath spectral functions. The form of the spectral functions can be tuned digitally, allowing for the time evolution of a wide range of open-system models at finite temperature. We study the feasibility of this approach with a focus on the solution of the spin-boson model and assume intrinsic qubit noise that is dominated by damping and dephasing. We find that classes of open quantum systems exist where our algorithm performs very well, even with gate errors as high as 1%. In general the presented algorithm performs best if the system-bath interactions can be decomposed into native gates.

Topics & Concepts

QubitDephasingQuantum computerNoise (video)Quantum algorithmQuantum gateComputer sciencePhysicsOpen quantum systemQuantumQuantum error correctionQuantum mechanicsAlgorithmStatistical physicsArtificial intelligenceImage (mathematics)Quantum Computing Algorithms and ArchitectureQuantum Information and CryptographyNeural Networks and Reservoir Computing
Quantum algorithm for solving open-system dynamics on quantum computers using noise | Litcius