Litcius/Paper detail

Gutzwiller hybrid quantum-classical computing approach for correlated materials

Yongxin Yao, Feng Zhang, Cai-Zhuang Wang, Kai-Ming Ho, Peter P. Orth

2021Physical Review Research39 citationsDOIOpen Access PDF

Abstract

Rapid progress in noisy intermediate-scale quantum (NISQ) computing technology has led to the development of novel resource-efficient hybrid quantum-classical algorithms, such as the variational quantum eigensolver (VQE), that can address open challenges in quantum chemistry, physics, and material science. Proof-of-principle quantum chemistry simulations for small molecules have been demonstrated on NISQ devices. While several approaches have been theoretically proposed for correlated materials, NISQ simulations of interacting periodic models on current quantum devices have not yet been demonstrated. Here, we develop a hybrid quantumclassical simulation framework for correlated electron systems based on the Gutzwiller variational embedding approach. We implement this framework on Rigetti quantum processing units (QPUs) and apply it to the periodic Anderson model, which describes a correlated heavy electron band hybridizing with noninteracting conduction electrons. Our simulation results quantitatively reproduce the known ground state quantum phase diagram including metallic, Kondo and Mott insulating phases. This is the first fully self-consistent hybrid quantum-classical simulation of an infinite correlated lattice model executed on QPUs, demonstrating that the Gutzwiller hybrid quantum-classical embedding framework is a powerful approach to simulate correlated materials on NISQ hardware. This benchmark study also puts forth a concrete pathway towards practical quantum advantage on NISQ devices.

Topics & Concepts

QuantumBenchmark (surveying)Quantum computerStatistical physicsEmbeddingComputer scienceGround stateQuantum algorithmPhysicsQuantum Monte CarloElectronic structureQuantum mechanicsAtomic orbitalLattice (music)Quantum simulatorHybrid functionalQuantum systemHybrid systemStrongly correlated materialPhase diagramAlgorithmQuantum gateState (computer science)Topology (electrical circuits)Quantum stateTheoretical computer scienceKondo effectComputational scienceElectronQuantum chemistryQuantum chemicalQuantum and electron transport phenomenaAdvanced Physical and Chemical Molecular InteractionsTopological Materials and Phenomena