Analog Quantum Simulation of Coupled Electron-Nuclear Dynamics in Molecules (2409.04427v1)

Abstract: Understanding the coupled electron-nuclear dynamics in molecules induced by light-matter interactions is crucial for potential applications of photochemical processes, but it is challenging due to the high computational costs of exact quantum dynamics simulations. Quantum computing has the potential to reduce the computational cost required for exact quantum dynamics simulations by exploiting the quantum nature of the computational device. However, existing quantum algorithms for coupled electron-nuclear dynamics simulation either require fault-tolerant devices, or use the Born-Oppenheimer (BO) approximation and a truncation of the electronic basis. In this work, we present the first analog quantum simulation approach for molecular vibronic dynamics in a pre-BO framework, i.e. without the separation of electrons and nuclei, by mapping the molecular Hamiltonian to a device with coupled qubits and bosonic modes. We show that our approach has exponential savings in resource and computational costs compared to the equivalent classical algorithms. The computational cost of our approach is also exponentially lower than existing BO-based quantum algorithms. Furthermore, our approach has a much smaller resource scaling than the existing pre-BO quantum algorithms for chemical dynamics. The low cost of our approach will enable an exact treatment of electron-nuclear dynamics on near-term quantum devices.