Classical Pauli repulsion: An anisotropic, atomic multipole model.


Journal article


Joshua A. Rackers, J. Ponder
Journal of Chemical Physics, 2019

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APA   Click to copy
Rackers, J. A., & Ponder, J. (2019). Classical Pauli repulsion: An anisotropic, atomic multipole model. Journal of Chemical Physics.


Chicago/Turabian   Click to copy
Rackers, Joshua A., and J. Ponder. “Classical Pauli Repulsion: An Anisotropic, Atomic Multipole Model.” Journal of Chemical Physics (2019).


MLA   Click to copy
Rackers, Joshua A., and J. Ponder. “Classical Pauli Repulsion: An Anisotropic, Atomic Multipole Model.” Journal of Chemical Physics, 2019.


BibTeX   Click to copy

@article{joshua2019a,
  title = {Classical Pauli repulsion: An anisotropic, atomic multipole model.},
  year = {2019},
  journal = {Journal of Chemical Physics},
  author = {Rackers, Joshua A. and Ponder, J.}
}

Abstract

Pauli repulsion is a key component of any theory of intermolecular interactions. Although Pauli or exchange repulsion has its origin in the quantum mechanical nature of electrons, it is possible to describe the resulting energetic effects via a classical model in terms of the overlap of electron densities. In fact, closed shell intermolecular repulsion can be explained as a diminution of election density in the internuclear region resulting in decreased screening of nuclear charges and increased nuclear-nuclear repulsion. We provide a concise anisotropic repulsion formulation using the atomic multipoles from the Atomic Multipole Optimized Energetics for Biomolecular Applications force field to describe the electron density at each atom in a larger system. Mathematically, the proposed model consists of damped pairwise exponential multipolar repulsion interactions truncated at short range, which are suitable for use in compute-intensive biomolecular force fields and molecular dynamics simulations. Parameters for 26 atom classes encompassing most organic molecules are derived from a fit to Symmetry Adapted Perturbation Theory exchange repulsion energies for the S101 dimer database. Several applications of the multipolar Pauli repulsion model are discussed, including noble gas interactions, analysis of stationary points on the water dimer potential surface, and the directionality of several halogen bonding interactions.


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