Peng He's research while affiliated with Nankai University and other places

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Publications (1)

Atomic structures of phosphorene (5 × 4 supercell) in the top view (a) and side view along the y direction (b), TCNQ (c), TCNE (d) and TTF (e).
Structural schematics of TCNQ/phosphorene (a), (b), TCNE/phosphorene (c), (d) and TTF/phosphorene (e), (f). The upper and lower ones represent the top and side views, respectively.
Band structures of isolated phosphorene (a), TCNQ/phosphorene (b), TCNE/phosphorene (c) and TTF/phosphorene (d). The Fermi level in each system is labeled by the red line.
Partial charge density of the CBM and VBM for TCNQ/phosphorene (a), TCNE/phosphorene (b) and TTF/phosphorene (c).
Structural schematics of PBL (a), TCNQ/PBL (b), TCNE/PBL (c) and TTF/PBL (d). The upper and lower ones represent the top and side views, respectively.

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Small molecules make big differences: Molecular doping effects on electronic and optical properties of phosphorene
  • Article
  • Full-text available

February 2015

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1,757 Reads

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160 Citations

Nanotechnology

Nanotechnology

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Peng He

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Panwen Shen

Systematical computations on the density functional theory were performed to investigate the adsorption of three typical organic molecules, tetracyanoquinodimethane (TCNQ), tetracyanoethylene (TCNE) and tetrathiafulvalene (TTF), on the surface of phosphorene monolayers and thicker layers. There exist considerable charge transfer and strong non-covalent interaction between these molecules and phosphorene. In particular, the band gap of phosphorene decreases dramatically due to the molecular modification and can be further tuned by applying an external electric field. Meanwhile, surface molecular modification has proven to be an effective way to enhance the light harvesting of phosphorene in different directions. Our results predict a flexible method toward modulating the electronic and optical properties of phosphorene and shed light on its experimental applications.

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Citations (1)

... This structure has two special directions: the zigzag direction, defined by the direction along which the zigzag chains run, and the armchair direction, defined by the interconnected chairs within each layer [54] ( Figure 3B). Remarkable in-plane anisotropic properties emerge from this unique structural arrangement, [55] which contribute to its electrical conductivity, [56] and to the optical, [57] mechanical, [58] and thermoelectric [59] properties. Even though the interactions between layers in BP are partly due to the presence of lone pairs of electrons on the phosphorus atoms, [60] for simplicity purposes they are often treated as van der Waals interactions. ...

Reference:

Emerging 2D Nanomaterials‐Integrated Hydrogels: Advancements in Designing Theragenerative Materials for Bone Regeneration and Disease Therapy
Small molecules make big differences: Molecular doping effects on electronic and optical properties of phosphorene
Nanotechnology

Nanotechnology

·

·

Peng He

·

[...]

·

Panwen Shen