Journal ArticleDOI
Charge-displacement analysis via natural orbitals for chemical valence: charge transfer effects in coordination chemistry.
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TLDR
A general scheme for disentangling donation and back-donation in the CD function of both symmetric and non-symmetric systems is presented and illustrated through applications to M-ethyne (M = Au, Ni and W) coordination bonds, including an explicative study on substrate activation in a model reaction mechanism.Abstract:
We recently devised a simple scheme for analyzing on quantitative grounds the Dewar-Chatt-Duncanson donation and back-donation in symmetric coordination complexes. Our approach is based on a symmetry decomposition of the so called Charge-Displacement (CD) function quantifying the charge flow, upon formation of a metal (M)-substrate (S) bond, along the M–S interaction axis and provides clear-cut measures of donation and back-donation charges in correlation with experimental observables [G. Bistoni et al., Angew. Chem., Int. Ed. 52, 11599 (2013)]. The symmetry constraints exclude of course from the analysis most systems of interest in coordination chemistry. In this paper, we show how to entirely overcome this limitation by taking advantage of the properties of the natural orbitals for chemical valence [M. Mitoraj and A. Michalak, J. Mol. Model. 13, 347 (2007)]. A general scheme for disentangling donation and back-donation in the CD function of both symmetric and non-symmetric systems is presented and illustrated through applications to M–ethyne (M = Au, Ni and W) coordination bonds, including an explicative study on substrate activation in a model reaction mechanism.read more
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Perspective: Found in translation: Quantum chemical tools for grasping non-covalent interactions.
TL;DR: This perspective provides an overview of tools and methods that have been specifically developed or used to analyze, identify, quantify, and visualize non-covalent interactions and their strengths, limitations, as well as a roadmap for expanding their capabilities are emphasized.
Journal ArticleDOI
Effect of Electron Correlation on Intermolecular Interactions: A Pair Natural Orbitals Coupled Cluster Based Local Energy Decomposition Study.
TL;DR: The local energy decomposition (LED) analysis is developed, which provides a chemically meaningful decomposition of the interaction energy between two or more fragments computed at the domain-based local pair natural orbitals coupled cluster (DLPNO-CCSD(T)) level of theory, used in conjunction with other interpretation tools to study a series of molecular adducts held together by intermolecular interactions of different natures.
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Theory Meets Experiment for Noncovalent Complexes: The Puzzling Case of Pnicogen Interactions
Weixing Li,Lorenzo Spada,Nicola Tasinato,Sergio Rampino,Luca Evangelisti,Andrea Gualandi,Pier Giorgio Cozzi,Sonia Melandri,Vincenzo Barone,Cristina Puzzarini +9 more
TL;DR: A gas-phase nitrogen-nitrogen noncovalent interaction has been unveiled in the nitroethane-trimethylamine complex in an environment free from solvent and matrix effects using rotational spectroscopy in supersonic expansion.
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Unveiling the Sulfur–Sulfur Bridge: Accurate Structural and Energetic Characterization of a Homochalcogen Intermolecular Bond
Daniel A. Obenchain,Lorenzo Spada,Silvia Alessandrini,Sergio Rampino,Sven Herbers,Nicola Tasinato,Marco Mendolicchio,Peter Kraus,Jürgen Gauss,Cristina Puzzarini,Jens-Uwe Grabow,Vincenzo Barone +11 more
TL;DR: By combining rotational spectroscopy in supersonic expansion with the capability of state-of-the-art quantum-chemical computations in accurately determining structural and energetic properties, the genuine nature of a sulfur-sulfur chalcogen bond between dimethyl sulfide and sulfur dioxide has been unveiled in a gas-jet environment free from collision, solvent and matrix perturbations.
Journal ArticleDOI
π Activation of Alkynes in Homogeneous and Heterogeneous Gold Catalysis
TL;DR: For the first time, the components of the Dewar-Chatt-Duncanson model, donation and back-donation, are put in quantitative correlation with the kinetic parameters of a chemical reaction.
References
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Towards an order-N DFT method
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