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Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems

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Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems. / Higham, J.; Henchman, R.H.
In: Journal of Computational Chemistry, Vol. 39, No. 12, 05.05.2018, p. 705-710.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Higham, J & Henchman, RH 2018, 'Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems', Journal of Computational Chemistry, vol. 39, no. 12, pp. 705-710. https://doi.org/10.1002/jcc.25137

APA

Higham, J., & Henchman, R. H. (2018). Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems. Journal of Computational Chemistry, 39(12), 705-710. https://doi.org/10.1002/jcc.25137

Vancouver

Higham J, Henchman RH. Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems. Journal of Computational Chemistry. 2018 May 5;39(12):705-710. doi: 10.1002/jcc.25137

Author

Higham, J. ; Henchman, R.H. / Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems. In: Journal of Computational Chemistry. 2018 ; Vol. 39, No. 12. pp. 705-710.

Bibtex

@article{c2affec3112e40b1aca9128d0406cf17,
title = "Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems",
abstract = "A common way to understand structure in multimolecular systems is the coordination shell which comprises all the neighbors of an atom. Coordination, however, is nontrivial to determine because there is no obvious way to determine when atoms are neighbors. A common solution is to take all atoms within a cutoff at the first minimum of the radial distribution function, g(r). We show that such an approach cannot be consistently applied to model multicomponent systems, namely mixtures of atoms differing in size or charge. Coordination shells using the total g(r) are found to be too restrictive for atoms of different size while those using pairwise g(r)s are excessive for charged mixtures. The recently introduced relative angular distance algorithm, however, which defines coordination instantaneously from atomic positions, is consistently able to define coordination shells containing the expected neighboring atoms for all these systems. This more robust way to determine coordination should in turn make coordination a more robust way to understand structure. ",
author = "J. Higham and R.H. Henchman",
year = "2018",
month = may,
day = "5",
doi = "10.1002/jcc.25137",
language = "English",
volume = "39",
pages = "705--710",
journal = "Journal of Computational Chemistry",
number = "12",

}

RIS

TY - JOUR

T1 - Overcoming the limitations of cutoffs for defining atomic coordination in multicomponent systems

AU - Higham, J.

AU - Henchman, R.H.

PY - 2018/5/5

Y1 - 2018/5/5

N2 - A common way to understand structure in multimolecular systems is the coordination shell which comprises all the neighbors of an atom. Coordination, however, is nontrivial to determine because there is no obvious way to determine when atoms are neighbors. A common solution is to take all atoms within a cutoff at the first minimum of the radial distribution function, g(r). We show that such an approach cannot be consistently applied to model multicomponent systems, namely mixtures of atoms differing in size or charge. Coordination shells using the total g(r) are found to be too restrictive for atoms of different size while those using pairwise g(r)s are excessive for charged mixtures. The recently introduced relative angular distance algorithm, however, which defines coordination instantaneously from atomic positions, is consistently able to define coordination shells containing the expected neighboring atoms for all these systems. This more robust way to determine coordination should in turn make coordination a more robust way to understand structure.

AB - A common way to understand structure in multimolecular systems is the coordination shell which comprises all the neighbors of an atom. Coordination, however, is nontrivial to determine because there is no obvious way to determine when atoms are neighbors. A common solution is to take all atoms within a cutoff at the first minimum of the radial distribution function, g(r). We show that such an approach cannot be consistently applied to model multicomponent systems, namely mixtures of atoms differing in size or charge. Coordination shells using the total g(r) are found to be too restrictive for atoms of different size while those using pairwise g(r)s are excessive for charged mixtures. The recently introduced relative angular distance algorithm, however, which defines coordination instantaneously from atomic positions, is consistently able to define coordination shells containing the expected neighboring atoms for all these systems. This more robust way to determine coordination should in turn make coordination a more robust way to understand structure.

U2 - 10.1002/jcc.25137

DO - 10.1002/jcc.25137

M3 - Journal article

VL - 39

SP - 705

EP - 710

JO - Journal of Computational Chemistry

JF - Journal of Computational Chemistry

IS - 12

ER -