Study of the Bound State, Electron-Detachment Energy and Reactivity of Hydride Ion using Variational Quantum Eigensolver

Abstract

The accurate prediction and understanding of molecular energy and chemical reactivity are fundamental pursuits in the field of molecular quantum chemistry. With the limitations of the current noisy intermediate scale quantum computer (NISQ) era, the Variational Quantum Eigensolver (VQE) algorithm offers a promising approach to efficiently estimate the stable energy state of a given molecule. This study is focused on predicting the ground state and single electron detachment energy of the hydride ion because of its high electron electron correlation and numerous applications in astrophysics and quantum chemistry. The hydride ion is the first three body quantum problem for which the ground state energy has been calculated theoretically using the Chandrasekhar Wavefunction, which takes high electron-electron correlation into account. For the calculation of hydride ion, we used the VQE algorithm with two types of quantum computational ansatz, (i) chemistry inspired ansatz based on unitary CC (UCC) and (ii) hardware efficient based ansatz (HEA). To check the versatility of the algorithm, we analyzed two proton transfer reactions involving the hydride ion and finds the energy to be exothermic with a much improved result compared to previous studies. Overall, the VQE algorithm with a quantum computational approach is found to be reliable in calculating stable state energy, single electron detachment energy, and reaction energy for proton transfer reactions involving a highly correlated molecule with a low relative percentage error.