Simulations of twisted bilayer orthorhombic black phosphorus

Douxing Pan; Tzu Chiang Wang; Wende Xiao; Dongmei Hu; Yugui Yao

doi:10.1103/PhysRevB.96.041411

Simulations of twisted bilayer orthorhombic black phosphorus

Douxing Pan, Tzu Chiang Wang^*, Wende Xiao, Dongmei Hu, Yugui Yao

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

30 Citations (Scopus)

Abstract

We identified, by means of coincidence site lattice theory, an evaluative stacking phase with a wavelike Moiré pattern, denoted as 2O-tαP, from all potentially twisted bilayer orthorhombic black phosphorus. Such a twisted stacking comes with a low formation energy of -162.8meV, very close to existing AB stacking, according to first-principles calculations. Particularly, classic molecular dynamic simulations verified that the stacking can be directly obtained in an in situ cleavage. The stability of 2O-tαP stacking can be directly attributed to the corrugated configuration of black phosphorus leading to the van der Waals constraining forces, where the top layer can get stuck to the bottom when one layer rotates in plane relative to the other by ∼70.5. Tribological analysis further revealed that the interlayer friction of 2O-tαP stacking reaches up to 1.3 nN, playing a key role in the origin of 2O-tαP.

Original language	English
Article number	041411
Journal	Physical Review B
Volume	96
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.96.041411
Publication status	Published - 27 Jul 2017

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title = "Simulations of twisted bilayer orthorhombic black phosphorus",

abstract = "We identified, by means of coincidence site lattice theory, an evaluative stacking phase with a wavelike Moir{\'e} pattern, denoted as 2O-tαP, from all potentially twisted bilayer orthorhombic black phosphorus. Such a twisted stacking comes with a low formation energy of -162.8meV, very close to existing AB stacking, according to first-principles calculations. Particularly, classic molecular dynamic simulations verified that the stacking can be directly obtained in an in situ cleavage. The stability of 2O-tαP stacking can be directly attributed to the corrugated configuration of black phosphorus leading to the van der Waals constraining forces, where the top layer can get stuck to the bottom when one layer rotates in plane relative to the other by ∼70.5. Tribological analysis further revealed that the interlayer friction of 2O-tαP stacking reaches up to 1.3 nN, playing a key role in the origin of 2O-tαP.",

author = "Douxing Pan and Wang, {Tzu Chiang} and Wende Xiao and Dongmei Hu and Yugui Yao",

note = "Publisher Copyright: {\textcopyright} 2017 American Physical Society.",

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doi = "10.1103/PhysRevB.96.041411",

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T1 - Simulations of twisted bilayer orthorhombic black phosphorus

AU - Pan, Douxing

AU - Wang, Tzu Chiang

AU - Xiao, Wende

AU - Hu, Dongmei

AU - Yao, Yugui

PY - 2017/7/27

Y1 - 2017/7/27

N2 - We identified, by means of coincidence site lattice theory, an evaluative stacking phase with a wavelike Moiré pattern, denoted as 2O-tαP, from all potentially twisted bilayer orthorhombic black phosphorus. Such a twisted stacking comes with a low formation energy of -162.8meV, very close to existing AB stacking, according to first-principles calculations. Particularly, classic molecular dynamic simulations verified that the stacking can be directly obtained in an in situ cleavage. The stability of 2O-tαP stacking can be directly attributed to the corrugated configuration of black phosphorus leading to the van der Waals constraining forces, where the top layer can get stuck to the bottom when one layer rotates in plane relative to the other by ∼70.5. Tribological analysis further revealed that the interlayer friction of 2O-tαP stacking reaches up to 1.3 nN, playing a key role in the origin of 2O-tαP.

AB - We identified, by means of coincidence site lattice theory, an evaluative stacking phase with a wavelike Moiré pattern, denoted as 2O-tαP, from all potentially twisted bilayer orthorhombic black phosphorus. Such a twisted stacking comes with a low formation energy of -162.8meV, very close to existing AB stacking, according to first-principles calculations. Particularly, classic molecular dynamic simulations verified that the stacking can be directly obtained in an in situ cleavage. The stability of 2O-tαP stacking can be directly attributed to the corrugated configuration of black phosphorus leading to the van der Waals constraining forces, where the top layer can get stuck to the bottom when one layer rotates in plane relative to the other by ∼70.5. Tribological analysis further revealed that the interlayer friction of 2O-tαP stacking reaches up to 1.3 nN, playing a key role in the origin of 2O-tαP.

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Simulations of twisted bilayer orthorhombic black phosphorus

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