The self‐consistent charge density functional tight‐binding theory study of carbon adatoms using tuned Hubbard <i>U</i> parameters

Wang, Jianpeng; Dai, Xing; Jiang, Wanrun; Yu, Tao

doi:10.1002/qua.25320

Int J of Quantum Chemistry

2016

DOI: 10.1002/qua.25320

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The self‐consistent charge density functional tight‐binding theory study of carbon adatoms using tuned Hubbard U parameters

Jianpeng Wang

Xing Dai

Wanrun Jiang

et al.

Abstract: The self‐consistent charge density functional tight‐binding (DFTB) theory is a useful tool for realizing the electronic structures of large molecular complex systems. In this study, the electronic structure of C61 formed by fullerene C60 with a carbon adatom is analyzed, using the fully localized limit and pseudo self‐interaction correction methods of DFTB to adjust the Hubbard U parameter (DFTB + U). The results show that both the methods used to adjust U can significantly reduce the molecular orbital energy … Show more

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Unusual spin-polarized electron state in fullerene induced by carbon adatom defect

Jiang

Wang

2017

Nanoscale

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First-principles calculations show that a carbon adatom defect at the Def[5, 6] site on the surface of C can produce a more stable spin-polarized singlet electronic state instead of a magnetic triplet state. This is clearly different from the cases of graphene and nanotubes. The mechanism results from the electron population of the adatom, which produces antiferromagnetic coupling around the C cage and the adatom itself. Our calculations show the same phenomenon occurs in other IPR fullerenes, such as C and C. These findings extend the understanding of the magnetic origin of pure carbon structures and are valuable for research related to the spin polarization of carbon systems.

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Unusual spin-polarized electron state in fullerene induced by carbon adatom defect

Jiang

Wang

2017

Nanoscale

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The self‐consistent charge density functional tight‐binding theory study of carbon adatoms using tuned Hubbard U parameters

Cited by 1 publication

References 53 publications

Unusual spin-polarized electron state in fullerene induced by carbon adatom defect

Unusual spin-polarized electron state in fullerene induced by carbon adatom defect

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