A Universal Quantitative Descriptor of the Dispersion Interaction Potential

Pollice, Robert; Chen, Peter

doi:10.1002/anie.201905439

Cited by 49 publications

(49 citation statements)

References 126 publications

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“…We additionally employed LD potential maps developed by Pollice and Chen to visualize these LD interactions (Supporting Information, Figure S2). [16] These confirm the conclusions drawn from the qualitative NCI analysis.…”

Section: Reconsidering Steric Effectssupporting

confidence: 81%

London Dispersion Interactions Rather than Steric Hindrance Determine the Enantioselectivity of the Corey–Bakshi–Shibata Reduction

2021

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The well‐known Corey–Bakshi–Shibata (CBS) reduction is a powerful method for the asymmetric synthesis of alcohols from prochiral ketones, often featuring high yields and excellent selectivities. While steric repulsion has been regarded as the key director of the observed high enantioselectivity for many years, we show that London dispersion (LD) interactions are at least as important for enantiodiscrimination. We exemplify this through a combination of detailed computational and experimental studies for a series of modified CBS catalysts equipped with dispersion energy donors (DEDs) in the catalysts and the substrates. Our results demonstrate that attractive LD interactions between the catalyst and the substrate, rather than steric repulsion, determine the selectivity. As a key outcome of our study, we were able to improve the catalyst design for some challenging CBS reductions.

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Section: Reconsidering Steric Effectssupporting

confidence: 81%

London Dispersion Interactions Rather than Steric Hindrance Determine the Enantioselectivity of the Corey–Bakshi–Shibata Reduction

2021

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“…The most conservative means of estimating such an error is to attribute the entire difference between the electrostatic interaction energies of 4 a and 4 b as arising from non‐transferrable hydridic repulsion, and to propagate this difference through all dependent dissected electrostatic and interaction energies (gray and black error bars in Figure , respectively). Even after making such a conservative error estimate, the total energy of the Au⋅⋅⋅Au interaction is found to be small in comparison to the ligand⋅⋅⋅ligand interactions that also occur within the dimer complex (Figure B, bottom), Consistent with recent examinations of aurophilic and stacking interactions, the energy decomposition analysis revealed that dispersion is the dominant attractive component in all of the stacked dimer fragments, but not the [Au] 2 dimer. Instead, the dissection suggests that the main stabilizing forces in the [Au] 2 dimer arise from either electrostatic or orbital interactions.…”

Section: Resultsmentioning

confidence: 99%

The Energetic Significance of Metallophilic Interactions

et al. 2019

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Metallophilic interactions are increasingly recognized as playing an important role in molecular assembly, catalysis, and bio‐imaging. However, present knowledge of these interactions is largely derived from solid‐state structures and gas‐phase computational studies rather than quantitative experimental measurements. Here, we have experimentally quantified the role of aurophilic (AuI⋅⋅⋅AuI), platinophilic (PtII⋅⋅⋅PtII), palladophilic (PdII⋅⋅⋅PdII), and nickelophilic (NiII⋅⋅⋅NiII) interactions in self‐association and ligand‐exchange processes. All of these metallophilic interactions were found to be too weak to be well‐expressed in several solvents. Computational energy decomposition analyses supported the experimental finding that metallophilic interactions are overall weak, meaning that favorable dispersion and orbital hybridization contributions from M⋅⋅⋅M binding are largely outcompeted by electrostatic or dispersion interactions involving ligand or solvent molecules. This combined experimental and computational study provides a general understanding of metallophilic interactions and indicates that great care must be taken to avoid over‐attributing the energetic significance of metallophilic interactions.

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“…We speculated that Et SbNMe2 could have formed via decomposition of a free rotation around the metal-nitrogen bonds allows overlap of the nitrogen lone pairs with metal-centred acceptor orbitals. Attractive dispersion forces 29 between the bulky trialkylsilyl groups (known to be excellent dispersion donors) 30 also play a significant role in stabilizing Et BiSb Et (∆Edisp = -39.03 kcal mol -1 ). Consistently, Bader's Atom-In-Molecules (AIM) 31 analysis detected numerous bond paths (Figure 1c, vertical green lines) and bond critical points (red dots) between the ligands on each metal showing peripheral attractive interactions between the bulky ligands.…”

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confidence: 99%