Computations with quantum harmonic oscillators or qumodes is a promising and rapidly evolving approach towards quantum computing. In contrast to qubits, which are two-level quantum systems, bosonic qumodes can in principle have infinite discrete levels, and can also be represented with continuous variable bases. One of the most promising applications of quantum computing is simulating many-fermion problems such as molecular electronic structure. Although there has been a lot of recent progress on simulating many-fermion systems on qubit-based quantum hardware, they can not be easily extended to bosonic quantum devices due to the fundamental difference in physics represented by qubits and qumodes. In this work, we show how an electronic structure Hamiltonian can be transformed into a system of qumodes with a fermion to boson mapping scheme and apply it to simulate the electronic structure of dihydrogen molecule as a system of two qumodes. Our work opens the door for simulating many-fermion systems by harnessing the power of bosonic quantum devices.
Comment: 47 pages including references, 7 figures, revised