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Simulating Large Quantum Circuits on a Small Quantum Computer

Tianyi Peng, Aram W. Harrow, Māris Ozols, Xiaodi Wu

2020Physical Review Letters269 citationsDOIOpen Access PDF

Abstract

Limited quantum memory is one of the most important constraints for near-term quantum devices. Understanding whether a small quantum computer can simulate a larger quantum system, or execute an algorithm requiring more qubits than available, is both of theoretical and practical importance. In this Letter, we introduce cluster parameters K and d of a quantum circuit. The tensor network of such a circuit can be decomposed into clusters of size at most d with at most K qubits of inter-cluster quantum communication. We propose a cluster simulation scheme that can simulate any (K,d)-clustered quantum circuit on a d-qubit machine in time roughly 2^{O(K)}, with further speedups possible when taking more fine-grained circuit structure into account. We show how our scheme can be used to simulate clustered quantum systems-such as large molecules-that can be partitioned into multiple significantly smaller clusters with weak interactions among them. By using a suitable clustered ansatz, we also experimentally demonstrate that a quantum variational eigensolver can still achieve the desired performance for estimating the energy of the BeH_{2} molecule while running on a physical quantum device with half the number of required qubits.

Topics & Concepts

Quantum computerQubitAnsatzQuantum algorithmQuantum circuitQuantumQuantum networkComputer scienceQuantum error correctionPhysicsOne-way quantum computerQuantum informationQuantum mechanicsTopology (electrical circuits)MathematicsCombinatoricsQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum many-body systems