Publication result detail

Large-scale synthesis of defect-free phosphorene on nickel substrates: enabling atomistic thickness devices

Tchoffo, DBT.; Benabdallah, I.; Aberda, A.; Neugebauer, P.; Belhboub, A.; El Fatimy, A.

Original Title

Large-scale synthesis of defect-free phosphorene on nickel substrates: enabling atomistic thickness devices

English Title

Large-scale synthesis of defect-free phosphorene on nickel substrates: enabling atomistic thickness devices

Type

WoS Article

Original Abstract

Addressing the main challenges of defect-free, large-scale synthesis of low-dimensional materials composed of phosphorus atoms is essential for advancing promising phosphorene-based technologies. Using molecular dynamics simulation, we demonstrate the large-scale and defect-free synthesis of phosphorene on Nickel (Ni) substrates. We showed that substrate orientation is crucial in the controllable synthesis of different phosphorene allotropes. Specifically, blue phosphorene was successfully grown on Ni (111) and Ni (100) surfaces, while gamma-phosphorene, referred to here as Navy phosphorene, was grown on Ni (110). In addition, temperature control (high temperature) and cooling rate (slow cooling) are also crucial in the formation of P6 hexagons. Finally, we report that the phosphorus pentamers (P5) are the essential precursor for phosphorene synthesis. This work provides a robust framework for understanding and controlling the synthesis of large-area, single-crystalline monolayer phosphorene.

English abstract

Addressing the main challenges of defect-free, large-scale synthesis of low-dimensional materials composed of phosphorus atoms is essential for advancing promising phosphorene-based technologies. Using molecular dynamics simulation, we demonstrate the large-scale and defect-free synthesis of phosphorene on Nickel (Ni) substrates. We showed that substrate orientation is crucial in the controllable synthesis of different phosphorene allotropes. Specifically, blue phosphorene was successfully grown on Ni (111) and Ni (100) surfaces, while gamma-phosphorene, referred to here as Navy phosphorene, was grown on Ni (110). In addition, temperature control (high temperature) and cooling rate (slow cooling) are also crucial in the formation of P6 hexagons. Finally, we report that the phosphorus pentamers (P5) are the essential precursor for phosphorene synthesis. This work provides a robust framework for understanding and controlling the synthesis of large-area, single-crystalline monolayer phosphorene.

Keywords

2D materials; chemical vapor deposition; phosphorene; molecular dynamics; growth mechanism

Key words in English

2D materials; chemical vapor deposition; phosphorene; molecular dynamics; growth mechanism

Authors

Tchoffo, DBT.; Benabdallah, I.; Aberda, A.; Neugebauer, P.; Belhboub, A.; El Fatimy, A.

RIV year

2025

Released

01.11.2024

Publisher

IOP Publishing Ltd

Location

BRISTOL

ISBN

1361-6463

Periodical

JOURNAL OF PHYSICS D-APPLIED PHYSICS

Volume

57

Number

43

State

United Kingdom of Great Britain and Northern Ireland

Pages count

9

URL

https://iopscience.iop.org/article/10.1088/1361-6463/ad61f7

BibTex

@article{BUT189338,
  author="Petr {Neugebauer} and Abdelouahad {El Fatimy} and D B Talonpa {Tchoffo} and Ismail {Benabdallah} and A. {Belhboub} and A. {Aberda}",
  title="Large-scale synthesis of defect-free phosphorene on nickel substrates: enabling atomistic thickness devices",
  journal="JOURNAL OF PHYSICS D-APPLIED PHYSICS",
  year="2024",
  volume="57",
  number="43",
  pages="9",
  doi="10.1088/1361-6463/ad61f7",
  issn="0022-3727",
  url="https://iopscience.iop.org/article/10.1088/1361-6463/ad61f7"
}