Schäfer Tobias, Libisch Florian, Kresse Georg, Grüneis Andreas
Institute for Theoretical Physics, TU Wien, Wiedner Hauptstraße 8-10/136, A-1040 Vienna, Austria.
University of Vienna, Faculty of Physics and Center for Computational Materials Science, Kolingasse 14-16, A-1090 Vienna, Austria.
J Chem Phys. 2021 Jan 7;154(1):011101. doi: 10.1063/5.0036363.
We present an embedding approach to treat local electron correlation effects in periodic environments. In a single consistent framework, our plane wave based scheme embeds a local high-level correlation calculation [here, Coupled Cluster (CC) theory], employing localized orbitals, into a low-level correlation calculation [here, the direct Random Phase Approximation (RPA)]. This choice allows for an accurate and efficient treatment of long-range dispersion effects. Accelerated convergence with respect to the local fragment size can be observed if the low-level and high-level long-range dispersions are quantitatively similar, as is the case for CC in RPA. To demonstrate the capabilities of the introduced embedding approach, we calculate adsorption energies of molecules on a surface and in a chabazite crystal cage, as well as the formation energy of a lattice impurity in a solid at the level of highly accurate many-electron perturbation theories. The absorption energy of a methane molecule in a zeolite chabazite is converged with an error well below 20 meV at the CC level. As our largest periodic benchmark system, we apply our scheme to the adsorption of a water molecule on titania in a supercell containing more than 1000 electrons.
我们提出了一种用于处理周期性环境中局域电子相关效应的嵌入方法。在一个统一的框架中,我们基于平面波的方案将采用定域轨道的局域高水平相关计算(此处为耦合簇(CC)理论)嵌入到低水平相关计算(此处为直接随机相位近似(RPA))中。这种选择能够精确且高效地处理长程色散效应。如果低水平和高水平的长程色散在数量上相似,就像RPA中的CC那样,那么就可以观察到相对于局域片段大小的加速收敛。为了展示所引入的嵌入方法的能力,我们在高精度多电子微扰理论水平下计算了分子在表面和菱沸石晶体笼中的吸附能,以及固体中晶格杂质的形成能。在CC水平下,甲烷分子在菱沸石中的吸附能收敛误差远低于20毫电子伏特。作为我们最大的周期性基准系统,我们将该方案应用于在包含超过1000个电子的超晶胞中水分子在二氧化钛上的吸附。
