Abstract
To facilitate computational investigation of intermolecular interactions in the solution phase, we report the development of ALMO-EDA(solv), a scheme that allows the application of continuum solvent models within the framework of energy decomposition analysis (EDA) based on absolutely localized molecular orbitals (ALMOs). In this scheme, all the quantum mechanical states involved in the variational EDA procedure are computed with the presence of solvent environment so that solvation effects are incorporated in the evaluation of all its energy components. After validation on several model complexes, we employ ALMO-EDA(solv) to investigate substituent effects on two classes of complexes that are related to molecular CO2 reduction catalysis. For [FeTPP(CO2-κC)]2− (TPP = tetraphenylporphyrin), we reveal that two ortho substituents which yield most favorable CO2 binding, –N(CH3)3+ (TMA) and –OH, stabilize the complex via through-structure and through-space mechanisms, respectively. The coulombic interaction between the positively charged TMA group and activated CO2 is found to be largely attenuated by the polar solvent. Furthermore, we also provide computational support for the design strategy of utilizing bulky, flexible ligands to stabilize activated CO2via long-range Coulomb interactions, which creates biomimetic solvent-inaccessible “pockets” in that electrostatics is unscreened. For the reactant and product complexes associated with the electron transfer from the p-terphenyl radical anion to CO2, we demonstrate that the double terminal substitution of p-terphenyl by electron-withdrawing groups considerably strengthens the binding in the product state while moderately weakens that in the reactant state, which are both dominated by the substituent tuning of the electrostatics component. These applications illustrate that this new extension of ALMO-EDA provides a valuable means to unravel the nature of intermolecular interactions and quantify their impacts on chemical reactivity in solution.
Highlights
Intermolecular interactions play an essential role in modern chemical research
To facilitate computational investigation of intermolecular interactions in the solution phase, we report the development of ALMO-EDA(solv), a scheme that allows the application of continuum solvent models within the framework of energy decomposition analysis (EDA) based on absolutely localized molecular orbitals (ALMOs)
To validate the treatment of solvent effects in ALMO-EDA(solv), we rst investigate a Na+/ClÀ model complex where the two ions are separated by 20 Aand immersed in solvent with varying dielectric constant described by conductor-like PCM (C-PCM)
Summary
Solution, making it desirable to develop computational chemistry tools to model and analyze intermolecular interactions with solvent effects taken into account. The EDA-PCM scheme developed by Su et al.,[41] which was based upon the localized molecular orbital (LMO)-EDA scheme,[42] is more closely related to the present work It accounts for the solvation environment in two stages: (i) the isolated fragment orbitals (LMOs) are optimized with continuum solvent, and are used to construct the intermediate states that are required for the evaluation of the electrostatics, exchange, repulsion, and polarization terms; (ii) a “desolvation” term, which describes the change in solute–. In the more recent generalized Kohn–Sham (GKS)-EDA,[43,44] this same approach is used to incorporate the solvent contribution to the interaction free energy While this is a rather sophisticated approach that integrates implicit solvation with a modern DFTbased EDA, the solvent reaction eld is constructed only for the initial (isolated fragment) and nal (full complex) states. Characterizing substrate–catalyst interactions, allowing one to understand the origin of activity or selectivity as well as the cause of any intrinsic limitation of a catalyst.[54,55,56,57] Many CO2 reduction catalysts operate in aprotic polar solvents,[51,52,53,58] aqueous solutions,[59] or water/organic solvent mixtures.[60,61] In such cases, it is essential to incorporate solvation effects in electronic structure calculations for one to obtain meaningful and reliable energetic results, especially for adducts of activated CO2 (CO2cÀ) whose interactions with other species would be vastly different in the gas and solution phases
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