Solid $C_{36} :$ Crystal structures, formation, and effects of doping

1 September 1999

journal article
research article
Published by American Physical Society (APS) in Physical Review B

Vol. 60 (10) , R6941-R6944
https://doi.org/10.1103/physrevb.60.r6941

Abstract

We employ plane-wave pseudopotential density functional calculations to show that the lowest energy

D_{6 h} C_{36}

crystal is a highly bonded network of hexagonal planes of

C_{36}

units with

AB

stacking. This crystal is significantly more dense and lower in energy than previously proposed structures. We demonstrate that Na is the largest alkali atom that can be intercalated into the crystal structure without causing severe structural distortion. Further, we predict the reaction pathway to form a neutral

C_{36}

dimer to be barrierless, while negatively charged

C_{36}

molecules are less likely to bond due to a substantial barrier of formation.

Keywords

This publication has 8 references indexed in Scilit:

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SolidC36:Crystal structures, formation, and effects of doping

Abstract

Keywords

Solid $C_{36} :$ Crystal structures, formation, and effects of doping