Experimental Quantum Simulation of Chemical Dynamics

Simulating chemistry is likely to be among the earliest applications of quantum computing. However, existing digital quantum algorithms for chemical simulation require many logical qubits and gates, placing practical applications beyond existing technology. Here, we use an analog approach to carry out the first quantum simulations of chemical reactions. In particular, we simulate photoinduced non-adiabatic dynamics, one of the most challenging classes of problems in quantum chemistry because they involve strong coupling and entanglement between electronic and nuclear motions. We use a mixed-qudit-boson (MQB) analog simulator, which encodes information in both the electronic and vibrational degrees of freedom of a trapped ion. We demonstrate its programmability and versatility by simulating the dynamics of three different molecules as well as open-system dynamics in the condensed phase, all with the same quantum resources. Our approach requires orders of magnitude fewer resources than equivalent digital quantum simulations, demonstrating the potential of analog quantum simulators for near-term simulations of complex chemical reactions.