Litcius/Paper detail

State Preparation in Quantum Algorithms for Fragment-Based Quantum Chemistry

Ruhee D’Cunha, Matthew Otten, Matthew R. Hermes, Laura Gagliardi, Stephen K. Gray

2024Journal of Chemical Theory and Computation16 citationsDOIOpen Access PDF

Abstract

State preparation for quantum algorithms is crucial for achieving high accuracy in quantum chemistry and competing with classical algorithms. The localized active space-unitary coupled cluster (LAS-UCC) algorithm iteratively loads a fragment-based multireference wave function onto a quantum computer. In this study, we compare two state preparation methods, quantum phase estimation (QPE) and direct initialization (DI), for each fragment. We test the two state preparation methods on three systems, ranging from a model system, a set of interacting hydrogen molecules, to more realistic chemical problems, like the C-C double bond breaking in transbutadiene and the spin ladder in a bimetallic system. We analyze the impact of QPE parameters, such as the number of ancilla qubits and Trotter steps, on the prepared state. We find a trade-off between the methods, where DI requires fewer resources for smaller fragments, while QPE is more efficient for larger fragments. Our resource estimates highlight the benefits of system fragmentation in state preparation for subsequent quantum chemical calculations. These findings have broad applications for preparing multireference quantum chemical wave functions on quantum circuits that can be used for realistic chemical applications.

Topics & Concepts

AlgorithmComputer scienceCoupled clusterQuantum chemistryQuantum algorithmQuantumWave functionQuantum computerQuantum stateInitializationQuantum chemicalChemistryQuantum mechanicsMoleculePhysicsProgramming languageSupramolecular chemistryQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyCloud Computing and Resource Management