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Probing resonating valence bonds on a programmable germanium quantum simulator

Chien-An Wang, Corentin Déprez, Hanifa Tidjani, William I. L. Lawrie, Nico W. Hendrickx, Amir Sammak, Giordano Scappucci, Menno Veldhorst

2023npj Quantum Information34 citationsDOIOpen Access PDF

Abstract

Abstract Simulations using highly tunable quantum systems may enable investigations of condensed matter systems beyond the capabilities of classical computers. Quantum dots and donors in semiconductor technology define a natural approach to implement quantum simulation. Several material platforms have been used to study interacting charge states, while gallium arsenide has also been used to investigate spin evolution. However, decoherence remains a key challenge in simulating coherent quantum dynamics. Here, we introduce quantum simulation using hole spins in germanium quantum dots. We demonstrate extensive and coherent control enabling the tuning of multi-spin states in isolated, paired, and fully coupled quantum dots. We then focus on the simulation of resonating valence bonds and measure the evolution between singlet product states which remains coherent over many periods. Finally, we realize four-spin states with s -wave and d -wave symmetry. These results provide means to perform non-trivial and coherent simulations of correlated electron systems.

Topics & Concepts

Quantum simulatorQuantum computerPhysicsQuantum decoherenceSpin engineeringOpen quantum systemQuantum technologyQuantum mechanicsQuantum networkQuantum dotValence bond theorySpinsQuantum sensorQuantumTopology (electrical circuits)Condensed matter physicsElectronSpin polarizationElectrical engineeringAtomic orbitalEngineeringQuantum and electron transport phenomenaSemiconductor Quantum Structures and DevicesQuantum Computing Algorithms and Architecture
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