Article,
Quantum Mechanical Versus Polarizable Embedding Schemes: A Study of the Xray Absorption Spectra of Aqueous Ammonia and Ammonium
Contributors
Folkestad, Sarai Dery
0000-0002-8569-4886
[1]
Paul, Alexander Christian
0000-0002-7547-445X
[1]
Matveeva, Regina Paul Née
0000-0001-6567-3570
[1]
Reinholdt, Peter
0000-0003-2406-700X
[2]
Coriani, Sonia
0000-0002-4487-897X
[3]
Odelius, Michael
0000-0002-7023-2486
[4]
Koch, Henrik
0000-0002-8367-8727
(Corresponding author)
[1]
Affiliations
- [1] Norwegian University of Science and Technology [NORA names: Norway; Europe, Non-EU; Nordic; OECD];
- [2] University of Southern Denmark [NORA names: SDU University of Southern Denmark; University; Denmark; Europe, EU; Nordic; OECD];
- [3] Technical University of Denmark [NORA names: DTU Technical University of Denmark; University; Denmark; Europe, EU; Nordic; OECD];
- [4] Stockholm University [NORA names: Sweden; Europe, EU; Nordic; OECD]
Abstract
The X-ray absorption spectra of aqueous ammonia and ammonium are computed using a combination of coupled cluster singles and doubles (CCSD) with different quantum mechanical and molecular mechanical embedding schemes. Specifically, we compare frozen Hartree-Fock (HF) density embedding, polarizable embedding (PE), and polarizable density embedding (PDE). Integrating CCSD with frozen HF density embedding is possible within the CC-in-HF framework, which circumvents the conventional system-size limitations of standard coupled cluster methods. We reveal similarities between PDE and frozen HF density descriptions, while PE spectra differ significantly. By including approximate triple excitations, we also investigate the effect of improving the electronic structure theory. The spectra computed using this approach show an improved intensity ratio compared to CCSD-in-HF. Charge transfer analysis of the excitations shows the local character of the pre-edge and main-edge, while the post-edge is formed by excitations delocalized over the first solvation shell and beyond.
