Litcius/Paper detail

Real- and Imaginary-Time Evolution with Compressed Quantum Circuits

Sheng-Hsuan Lin, Rohit Dilip, Andrew G. Green, Adam Smith, Frank Pollmann

2021PRX Quantum199 citationsDOIOpen Access PDF

Abstract

The current generation of noisy intermediate-scale quantum computers introduces new opportunities to study quantum many-body systems. In this paper, we show that quantum circuits can provide a dramatically more efficient representation than current classical numerics of the quantum states generated under nonequilibrium quantum dynamics. For quantum circuits, we perform both real-and imaginary-time evolution using an optimization algorithm that is feasible on near-term quantum computers. We benchmark the algorithms by finding the ground state and simulating a global quench of the transverse-field Ising model with a longitudinal field on a classical computer. Furthermore, we implement (classically optimized) gates on a quantum processing unit and demonstrate that our algorithm effectively captures real-time evolution.

Topics & Concepts

Quantum algorithmQuantum computerQuantumQuantum error correctionQuantum phase estimation algorithmQuantum gateQuantum annealingComputer sciencePhysicsQuantum circuitBenchmark (surveying)Quantum networkIsing modelStatistical physicsQuantum stateQuantum technologyOpen quantum systemQuantum informationQuantum processAlgorithmRepresentation (politics)Quantum simulatorQuantum operationQuantum logicQuantum mechanicsElectronic circuitQuantum sensorOne-way quantum computerQuantum dynamicsState (computer science)Current (fluid)Field (mathematics)Quantum channelGround stateTheoretical computer scienceQuantum metrologyMathematicsQuantum Computing Algorithms and ArchitectureQuantum many-body systemsNeural Networks and Reservoir Computing
Real- and Imaginary-Time Evolution with Compressed Quantum Circuits | Litcius