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Quantum Simulation of Open Quantum Systems Using a Unitary Decomposition of Operators

Anthony W. Schlimgen, Kade Head-Marsden, LeeAnn M. Sager-Smith, Prineha Narang, David A. Mazziotti

2021Physical Review Letters122 citationsDOIOpen Access PDF

Abstract

Electron transport in realistic physical and chemical systems often involves the nontrivial exchange of energy with a large environment, requiring the definition and treatment of open quantum systems. Because the time evolution of an open quantum system employs a nonunitary operator, the simulation of open quantum systems presents a challenge for universal quantum computers constructed from only unitary operators or gates. Here, we present a general algorithm for implementing the action of any nonunitary operator on an arbitrary state on a quantum device. We show that any quantum operator can be exactly decomposed as a linear combination of at most four unitary operators. We demonstrate this method on a two-level system in both zero and finite temperature amplitude damping channels. The results are in agreement with classical calculations, showing promise in simulating nonunitary operations on intermediate-term and future quantum devices.

Topics & Concepts

Open quantum systemQuantum operationUnitary operatorOperator (biology)Quantum processQuantum algorithmQuantumUnitary stateQuantum systemQuantum mechanicsQuantum stateOpen system (computing)PhysicsQuantum computerComputer scienceQuantum dynamicsHilbert spaceLawGeneProgramming languageSoftwareTranscription factorPolitical scienceBiochemistryRepressorChemistryQuantum and electron transport phenomenaNeural Networks and Reservoir ComputingQuantum Computing Algorithms and Architecture