Ab initio Study of the Interactions between CO2 and N-Containing Organic Heterocycles

Ab initio Study of the Interactions between CO2 and N-Containing Organic Heterocycles

In the garden of dispersion: High‐accuracy ab initio calculations are performed to determine the nature of the interactions and the most favorable geometries between CO2 and heteroaromatic molecules containing nitrogen (see figure). Dispersion forces play a key role in the stabilization of the dimer...

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Bibliographic Details
Published in:Chemphyschem Vol. 10; no. 2; pp. 374 - 383
Main Authors: Vogiatzis, Konstantinos D., Mavrandonakis, Andreas, Klopper, Wim, Froudakis, George E.
Format: Journal Article
Language:English
Published: Weinheim WILEY-VCH Verlag 02-02-2009
WILEY‐VCH Verlag
Wiley
Subjects:
Ab initio calculations
Atomic and molecular collision processes and interactions
Atomic and molecular physics
Calculations and mathematical techniques in atomic and molecular physics (excluding electron correlation calculations)
carbon dioxide
Coupled cluster theory
Density-functional theory
donor-acceptor systems
Electronic structure of atoms, molecules and their ions: theory
Exact sciences and technology
hydrogen bonds
Interatomic and intermolecular potentials and forces, potential energy surfaces for collisions
Intermolecular and atom-molecule potentials and forces
Physics
weak interactions
Imidazole derivatives
Purine derivatives
Tetrazole derivatives
donor- acceptor systems . hydrogen bonds
Weak interactions
Nitrogen heterocycle
Carbon dioxide
Adenines
Planar configuration
Pyridine derivatives
Intermolecular interaction
Geometrical structure
Hydrogen bonds
Pyridazine derivatives
Ab initio calculations
Electron density
Triatomic molecule
Moller Plesset partition
Organic compounds
Pyrazine derivatives
Theoretical study
Electron correlations
Binding energy
Triazine derivatives
Density functional method
Pyrimidine derivatives
Multiple excitation
Coupled cluster method
Electrostatic potential
Donor acceptor interaction
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Summary:In the garden of dispersion: High‐accuracy ab initio calculations are performed to determine the nature of the interactions and the most favorable geometries between CO2 and heteroaromatic molecules containing nitrogen (see figure). Dispersion forces play a key role in the stabilization of the dimer, because correlation effects represent about 50 % of the total interaction energy. The interactions between carbon dioxide and organic heterocyclic molecules containing nitrogen are studied by using high‐accuracy ab initio methods. Various adsorption positions are examined for pyridine. The preferred configuration is an in‐plane configuration. An electron donor–electron acceptor (EDA) mechanism between the carbon of CO2 and the nitrogen of the heterocycle and weak hydrogen bonds stabilize the complex, with important contributions from dispersion and induction forces. Quantitative results of the binding energy of CO2 to pyridine (C5H5N), pyrimidine, pyridazine, and pyrazine (C4H4N2), triazine (C3H3N3), imidazole (C3H4N2), tetrazole (CH2N4), purine (C5H4N4), imidazopyridine (C6H5N3), adenine (C5H5N5), and imidazopyridamine (C6H6N4) for the in‐plane configuration are presented. For purine, three different binding sites are examined. An approximate coupled‐cluster model including single and double excitations with a perturbative estimation of triple excitations (CCSD(T)) is used for benchmark calculations. The CCSD(T) basis‐set limit is approximated from explicitly correlated second‐order Møller–Plesset (MP2‐F12) calculations in the aug‐cc‐pVTZ basis in conjunction with contributions from single, double, and triple excitations calculated at the CCSD(T)/6‐311++G** level of theory. Extrapolations to the MP2 basis‐set limit coincide with the MP2‐F12 calculations. The results are interpreted in terms of electrostatic potential maps and electron density redistribution plots. The effectiveness of density functional theory with the empirical dispersion correction of Grimme (DFT‐D) is also examined. In the garden of dispersion: High‐accuracy ab initio calculations are performed to determine the nature of the interactions and the most favorable geometries between CO2 and heteroaromatic molecules containing nitrogen (see figure). Dispersion forces play a key role in the stabilization of the dimer, because correlation effects represent about 50 % of the total interaction energy.
Bibliography:ark:/67375/WNG-LXH44HFP-S
Alexander von Humboldt Foundation
DAAD Programm Griechenland IKYDA 2006
Deutsche Forschungsgemeinschaft
ArticleID:CPHC200800583
istex:BB9B67C6D5019E787047C18186FFEEEFD7F2D0B6
Ministry of Science, Research and the Arts of Baden-Württemberg - No. 7713.14-300
ISSN:1439-4235
1439-7641
DOI:10.1002/cphc.200800583