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Gate-free state preparation for fast variational quantum eigensolver simulations

Oinam Romesh Meitei, Bryan Gard, George S. Barron, David P. Pappas, Sophia E. Economou, Edwin Barnes, Nicholas J. Mayhall

2021npj Quantum Information80 citationsDOIOpen Access PDF

Abstract

Abstract The variational quantum eigensolver is currently the flagship algorithm for solving electronic structure problems on near-term quantum computers. The algorithm involves implementing a sequence of parameterized gates on quantum hardware to generate a target quantum state, and then measuring the molecular energy. Due to finite coherence times and gate errors, the number of gates that can be implemented remains limited. In this work, we propose an alternative algorithm where device-level pulse shapes are variationally optimized for the state preparation rather than using an abstract-level quantum circuit. In doing so, the coherence time required for the state preparation is drastically reduced. We numerically demonstrate this by directly optimizing pulse shapes which accurately model the dissociation of H 2 and HeH + , and we compute the ground state energy for LiH with four transmons where we see reductions in state preparation times of roughly three orders of magnitude compared to gate-based strategies.

Topics & Concepts

Quantum computerParameterized complexityQuantum circuitCoherence (philosophical gambling strategy)QuantumComputer scienceQuantum algorithmQuantum gateGate countCoherence timeAlgorithmState (computer science)Quantum error correctionTopology (electrical circuits)Quantum mechanicsPhysicsElectrical engineeringComputer hardwareEngineeringQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomenaQuantum Information and Cryptography
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