Related papers: Real-time equation-of-motion CC cumulant and CC Green's function simulations of photoemission spectra of water and water dimer

Real-time equation-of-motion CC cumulant and CC Green's function simulations of photoemission spectra of water and water dimer

URL: http://arxiv.org/abs/2205.14179v1
Date: Fri, 27 May 2022 18:16:30 GMT
Title: Real-time equation-of-motion CC cumulant and CC Green's function simulations of photoemission spectra of water and water dimer
Authors: Fernando D. Vila, John J. Rehr, Himadri Pathak, Bo Peng, Ajay Panyala, Erdal Mutlu, Nicholas P. Bauman, Karol Kowalski
Abstract summary: We discuss results obtained with the real-time equation-of-motion CC cumulant approach. We compare the ionization potentials obtained with these methods for the valence region. We analyze unique features of the spectral functions, associated with the position of satellite peaks, obtained with the RT-EOM-CC and CCGF methods.
Score: 54.44073730234714
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Newly developed coupled-cluster (CC) methods enable simulations of ionization potentials and spectral functions of molecular systems in a wide range of energy scales ranging from core-binding to valence. This paper discusses results obtained with the real-time equation-of-motion CC cumulant approach (RT-EOM-CC), and CC Green's function (CCGF) approaches in applications to the water and water dimer molecules. We compare the ionization potentials obtained with these methods for the valence region with the results obtained with the CCSD(T) formulation as a difference of energies for N and N-1 electron systems. All methods show good agreement with each other. They also agree well with experiment, with errors usually below 0.1 eV for the ionization potentials. We also analyze unique features of the spectral functions, associated with the position of satellite peaks, obtained with the RT-EOM-CC and CCGF methods employing single and double excitations, as a function of the monomer OH bond length and the proton transfer coordinate in the dimer. Finally, we analyze the impact of the basis set effects on the quality of calculated ionization potentials and find that the basis set effects are less pronounced for the augmented-type sets.

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