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Unusually Stable Helical Coil Allotrope of Phosphorus
Abstract
We have identified an unusually stable helical coil allotrope of phosphorus. Our ab initio density functional theory calculations indicate that the uncoiled, isolated straight one-dimensional chain is equally stable as a monolayer of black phosphorus dubbed phosphorene. The coiling tendency and the attraction between adjacent coil segments add an extra stabilization energy of ∼12 meV/atom to the coil allotrope, similar in value to the ∼16 meV/atom interlayer attraction in bulk black phosphorus. Thus, the helical coil structure is essentially as stable as black phosphorus, the most stable phosphorus allotrope known to date. With an optimum radius of 2.4 nm, the helical coil of phosphorus may fit well and even form inside wide carbon nanotubes- Dataset
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- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- theory calculations
- coil segments
- helical coil structure
- stabilization energy
- phosphorus allotrope
- Unusually Stable Helical Coil Allotrope
- helical coil
- carbon nanotubes
- helical coil allotrope
- coil allotrope
- ab initio density
- 2.4 nm