A static quantum embedding scheme based on coupled cluster theory

We develop a static quantum embedding scheme, utilizing projection equations to solve coupled cluster (CC) amplitudes. To reduce the computational cost (for example, of a large basis set calculation), we solve the local fragment problem using a high-level coupled cluster method and address the environment problem with a lower-level Møller-Plesset (MP) perturbative method. This embedding approach is consistently formulated within the coupled cluster framework and will be called MP-CC. We demonstrate the effectiveness of our method through several prototypical molecular examples by analyzing a global quantity, that is, the total correlation energy of the system in the study of potential energy curves (PEC) and thermochemical reaction energies. We have shown that our method can achieve comparable accuracy both with a small and large basis set when the fragment Hilbert space size remains the same. Additionally, our results indicate that increasing the fragment size can systematically enhance the accuracy of observables, approaching the precision of the full coupled cluster solver.