Anthony S. Mitchell scite author profile

A new way of exploring packing modes and intermolecular interactions in molecular crystals is described, using Hirshfeld surfaces to partition crystal space. These molecular Hirshfeld surfaces, so named because they derive from Hirshfeld's stockholder partitioning, divide the crystal into regions where the electron distribution of a sum of spherical atoms for the molecule (the promolecule) dominates the corresponding sum over the crystal (the procrystal). These surfaces reflect intermolecular interactions in a novel visual manner, offering a previously unseen picture of molecular shape in a crystalline environment. Surface features characteristic of different types of intermolecular interactions can be identified, and such features can be revealed by colour coding distances from the surface to the nearest atom exterior or interior to the surface, or by functions of the principal surface curvatures. These simple devices provide a striking and immediate picture of the types of interactions present, and even reflect their relative strengths from molecule to molecule. A complementary two-dimensional mapping is also presented, which summarizes quantitatively the types of intermolecular contacts experienced by molecules in the bulk and presents this information in a convenient colour plot. This paper describes the use of these tools in the compilation of a pictorial glossary of intermolecular interactions, using identifiable patterns of interaction between small molecules to rationalize the often complex mix of interactions displayed by large molecules.

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Hirshfeld Surfaces: A New Tool for Visualising and Exploring Molecular Crystals

McKinnon

1998

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A remarkable new way of exploring molecular crystals is afforded by isosurface rendering of smooth, nonoverlapping molecular surfaces arising from a partitioning of crystal space based on Hirshfelds stockholder partitioning scheme. These surfaces reflect the proximity of neighbouring atoms and molecules, and hence intermolecular interactions, in a novel visual manner which offers a hitherto unseen picture of molecular shape in a crystalline environment. This work reports 3D isosurface pictures of these molecular surfaces, which we call Hirshfeld surfaces, as well as a number of quantitative measures of molecular size and global shape, applied to a variety of simple molecular crystals. Implications for the exploration of crystal packing and crystal engineering are discussed.

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XSophe-Sophe-XeprView ® . A computer simulation software suite (v. 1.1.3) for the analysis of continuous wave EPR spectra

Hanson

Gates

Noble

et al. 2004

Journal of Inorganic Biochemistry

258

273

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Basis set choice and basis set superposition error (BSSE) in periodic Hartree–Fock calculations on molecular crystals

Spackman

Mitchell

2001

Phys. Chem. Chem. Phys.

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Molecular surfaces from the promolecule: A comparison with Hartree-Fockab initio electron density surfaces

Mitchell

Spackman

2000

J. Comput. Chem.

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Annulation reactions with stabilized phthalide anions

1995

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XSophe — Sophe — XeprView

Hanson

Gates

Noble

et al. 2003

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Molecular surfaces from the promolecule: A comparison with Hartree–Fock ab initio electron density surfaces

Mitchell

Spackman

2000

J. Comput. Chem.

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ABSTRACT:A new molecular surface, the promolecule electron density isosurface arising from the superposition of spherical atomic electron density functions, is compared and contrasted with the Hartree-Fock ab initio electron density isosurface, the fused-sphere van der Waals (CPK) surface, and the smooth Connolly surface. From application to a number of small to medium-sized molecules, including several amino acids, the promolecule surface is shown to be very similar to the Hartree-Fock electron density isosurface but, in contrast, is trivial to calculate. The promolecule electron density surface constructed with a contracted hydrogen atom provides remarkably reliable, and consistent, estimates of ab initio surface areas (typically within 0.5%) and volumes (routinely overestimated by less than 4%). Differences between ab initio and promolecule surfaces are explored visually by mapping the deformation density on the promolecule surface. To highlight the usefulness of the promolecule surface, a promolecule 0.002 au isosurface of the small protein crambin is shown.

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