AI Article Synopsis
- The multilevel coupled cluster approach allows for treating an active orbital space with higher precision than the inactive orbitals, specifically using CC2 for active spaces and a simplified CCSD method for inactive spaces.
- A simplified formulation helps in efficiently calculating CC2 amplitudes from previously determined values, employing correlated natural transition orbitals to define the active orbital spaces.
- The effectiveness of these multilevel methods is demonstrated through calculations on -nitroaniline in water and amoxicillin, showcasing their utility for studying molecules in solution and charge transfer excitations.
Article Abstract
In the multilevel coupled cluster approach, an active orbital space is treated at a higher level of coupled cluster theory than the remaining inactive orbitals. We introduce the multilevel CC2 method where CC2 is used for the active orbital space. Furthermore, we present a simplified formulation of the multilevel CCSD method where CCSD is used for the active space. The simplification lies in the evaluation of the CC2 amplitudes in the inactive space; these CC2 amplitudes have previously been determined iteratively. We use correlated natural transition orbitals to determine the active orbital spaces. The convergence of the multilevel CC2 and multilevel CCSD valence excitation energies is established with proof-of-concept calculations. The methods are also applied to two larger systems: -nitroaniline in water and amoxicillin. The calculations on the -nitroaniline-water system illustrate the usefulness of multilevel coupled cluster methods for molecules in solution and for charge transfer excitations.
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| http://dx.doi.org/10.1021/acs.jctc.9b00701 | DOI Listing |
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