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Quantum computation for periodic solids in second quantization

Aleksei V. Ivanov, Christoph Sünderhauf, Nicole Holzmann, Tom Ellaby, Rachel N. Kerber, Glenn Jones, Joan Camps

2023Physical Review Research33 citationsDOIOpen Access PDF

Abstract

In this work, we present a quantum algorithm for ground-state energy calculations of periodic solids on error-corrected quantum computers. The algorithm is based on the sparse qubitization approach in second quantization and developed for Bloch and Wannier basis sets. We show that Wannier functions require less computational resources with respect to Bloch functions because (i) the ${\mathrm{L}}_{1}$ norm of the Hamiltonian is considerably lower and (ii) the translational symmetry of Wannier functions can be exploited in order to reduce the amount of classical data that must be loaded into the quantum computer. The resource requirements of the quantum algorithm are estimated for periodic solids such as NiO and PdO. These transition metal oxides are industrially relevant for their catalytic properties. We find that ground-state energy estimation of Hamiltonians approximated using 200--900 spin orbitals requires ca. ${10}^{10}$--${10}^{12}$ T gates and up to $3\ifmmode\times\else\texttimes\fi{}{10}^{8}$ physical qubits for a physical error rate of $0.1%$.

Topics & Concepts

Wannier functionQuantum computerHamiltonian (control theory)Quantum mechanicsQubitTranslational symmetryPhysicsQuantumAtomic orbitalQuantization (signal processing)Quantum algorithmGround stateStatistical physicsMathematicsCondensed matter physicsAlgorithmMathematical optimizationElectronQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomenaQuantum-Dot Cellular Automata
Quantum computation for periodic solids in second quantization | Litcius