Manipulation of electron transport in graphene by nanopatterned electrostatic potential on an electret

Xiaowei Wang; Rui Wang; Shengnan Wang; Dongdong Zhang; Xingbin Jiang; Zhihai Cheng; Xiaohui Qiu

doi:10.1063/1.5006226

Manipulation of electron transport in graphene by nanopatterned electrostatic potential on an electret

Xiaowei Wang
, Rui Wang
, Shengnan Wang
, Dongdong Zhang
, Xingbin Jiang
, Zhihai Cheng
, Xiaohui Qiu

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

3 Scopus citations

Abstract

The electron transport characteristics of graphene can be finely tuned using local electrostatic fields. Here, we use a scanning probe technique to construct a statically charged electret gate that enables in-situ fabrication of graphene devices with precisely designed potential landscapes, including p-type and n-type unipolar graphene transistors and p-n junctions. Electron dynamic simulation suggests that electron beam collimation and focusing in graphene can be achieved via periodic charge lines and concentric charge circles. This approach to spatially manipulating carrier density distribution may offer an efficient way to investigate the novel electronic properties of graphene and other low-dimensional materials.

Original language	English
Article number	033102
Journal	Applied Physics Letters
Volume	112
Issue number	3
DOIs	https://doi.org/10.1063/1.5006226
State	Published - 15 Jan 2018
Externally published	Yes

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10.1063/1.5006226

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title = "Manipulation of electron transport in graphene by nanopatterned electrostatic potential on an electret",

abstract = "The electron transport characteristics of graphene can be finely tuned using local electrostatic fields. Here, we use a scanning probe technique to construct a statically charged electret gate that enables in-situ fabrication of graphene devices with precisely designed potential landscapes, including p-type and n-type unipolar graphene transistors and p-n junctions. Electron dynamic simulation suggests that electron beam collimation and focusing in graphene can be achieved via periodic charge lines and concentric charge circles. This approach to spatially manipulating carrier density distribution may offer an efficient way to investigate the novel electronic properties of graphene and other low-dimensional materials.",

author = "Xiaowei Wang and Rui Wang and Shengnan Wang and Dongdong Zhang and Xingbin Jiang and Zhihai Cheng and Xiaohui Qiu",

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T1 - Manipulation of electron transport in graphene by nanopatterned electrostatic potential on an electret

AU - Wang, Xiaowei

AU - Wang, Rui

AU - Wang, Shengnan

AU - Zhang, Dongdong

AU - Jiang, Xingbin

AU - Cheng, Zhihai

AU - Qiu, Xiaohui

PY - 2018/1/15

Y1 - 2018/1/15

N2 - The electron transport characteristics of graphene can be finely tuned using local electrostatic fields. Here, we use a scanning probe technique to construct a statically charged electret gate that enables in-situ fabrication of graphene devices with precisely designed potential landscapes, including p-type and n-type unipolar graphene transistors and p-n junctions. Electron dynamic simulation suggests that electron beam collimation and focusing in graphene can be achieved via periodic charge lines and concentric charge circles. This approach to spatially manipulating carrier density distribution may offer an efficient way to investigate the novel electronic properties of graphene and other low-dimensional materials.

AB - The electron transport characteristics of graphene can be finely tuned using local electrostatic fields. Here, we use a scanning probe technique to construct a statically charged electret gate that enables in-situ fabrication of graphene devices with precisely designed potential landscapes, including p-type and n-type unipolar graphene transistors and p-n junctions. Electron dynamic simulation suggests that electron beam collimation and focusing in graphene can be achieved via periodic charge lines and concentric charge circles. This approach to spatially manipulating carrier density distribution may offer an efficient way to investigate the novel electronic properties of graphene and other low-dimensional materials.

UR - https://www.scopus.com/pages/publications/85040715244

U2 - 10.1063/1.5006226

DO - 10.1063/1.5006226

M3 - 文章

AN - SCOPUS:85040715244

SN - 0003-6951

VL - 112

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 3

M1 - 033102

ER -

Manipulation of electron transport in graphene by nanopatterned electrostatic potential on an electret

Abstract

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