Ab Initio Transcorrelated Method enabling accurate Quantum Chemistry on near-term Quantum Hardware
read the original abstract
Quantum computing is emerging as a new computational paradigm with the potential to transform several research fields, including quantum chemistry. However, current hardware limitations (including limited coherence times, gate infidelities, and limited connectivity) hamper the straightforward implementation of most quantum algorithms and call for more noise-resilient solutions. In quantum chemistry, the limited number of available qubits and gate operations is particularly restrictive since, for each molecular orbital, one needs, in general, two qubits. In this study, we propose an explicitly correlated Ansatz based on the transcorrelated (TC) approach, which transfers -- without any approximation -- correlation from the wavefunction directly into the Hamiltonian, thus reducing the number of resources needed to achieve accurate results with noisy, near-term quantum devices. In particular, we show that the exact transcorrelated approach not only allows for more shallow circuits but also improves the convergence towards the so-called basis set limit, providing energies within chemical accuracy to experiment with smaller basis sets and, therefore, fewer qubits. We demonstrate our method by computing bond lengths, dissociation energies, and vibrational frequencies close to experimental results for the hydrogen dimer and lithium hydride using just 4 and 6 qubits, respectively. Conventional methods require at least ten times more qubits for the same accuracy.
This paper has not been read by Pith yet.
Forward citations
Cited by 3 Pith papers
-
Quantum simulation of molecular excited-state manifolds and energies using the TEPID-ADAPT-VQE algorithm
TEPID-ADAPT-VQE computes excited-state spectra and potential energy surfaces for H2, LiH, and linear H4 within chemical accuracy using adaptive VQE on a truncated Gibbs state with a single temperature hyperparameter.
-
Accuracy and resource advantages of quantum eigenvalue estimation with non-Hermitian transcorrelated electronic Hamiltonians
QEVE on xTC transcorrelated Hamiltonians in STO-6G basis achieves T-gate counts between standard qubitization in cc-pVTZ and cc-pVQZ while delivering accuracy better than cc-pVQZ for Li and Be but worse than cc-pVDZ f...
-
Quantum Computing Beyond Ground State Electronic Structure: A Review of Progress Toward Quantum Chemistry Out of the Ground State
Review of quantum computing methods and potential for non-ground-state quantum chemistry including reaction dynamics, mechanisms, and finite temperatures.
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.