Electronic properties of polycrystalline graphene under large local strain

Xin He; Li Gao; Ning Tang; Junxi Duan; Fuhong Mei; Hu Meng; Fangchao Lu; Fujun Xu; Xinqiang Wang; Xuelin Yang; Weikun Ge; Bo Shen

doi:10.1063/1.4883866

Electronic properties of polycrystalline graphene under large local strain

Xin He, Li Gao, Ning Tang, Junxi Duan, Fuhong Mei, Hu Meng, Fangchao Lu, Fujun Xu, Xinqiang Wang, Xuelin Yang, Weikun Ge, Bo Shen

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

17 Citations (Scopus)

Abstract

To explore the transport properties of polycrystalline graphene under large tensile strain, a strain device has been fabricated using piezocrystal to load local strain onto graphene, up to 22.5%. Ionic liquid gate whose capability of tuning carrier density being much higher than that of a solid gate is used to survey the transfer characteristics of the deformed graphene. The conductance of the Dirac point and field effect mobility of electrons and holes is found to decrease with increasing strain, which is attributed to the scattering of the graphene grain boundaries, the strain induced change of band structure, and defects. However, the transport gap is still not opened. Our study is helpful to evaluate the application of graphene in stretchable electronics.

Original language	English
Article number	243108
Journal	Applied Physics Letters
Volume	104
Issue number	24
DOIs	https://doi.org/10.1063/1.4883866
Publication status	Published - 16 Jun 2014
Externally published	Yes

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abstract = "To explore the transport properties of polycrystalline graphene under large tensile strain, a strain device has been fabricated using piezocrystal to load local strain onto graphene, up to 22.5%. Ionic liquid gate whose capability of tuning carrier density being much higher than that of a solid gate is used to survey the transfer characteristics of the deformed graphene. The conductance of the Dirac point and field effect mobility of electrons and holes is found to decrease with increasing strain, which is attributed to the scattering of the graphene grain boundaries, the strain induced change of band structure, and defects. However, the transport gap is still not opened. Our study is helpful to evaluate the application of graphene in stretchable electronics.",

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T1 - Electronic properties of polycrystalline graphene under large local strain

AU - He, Xin

AU - Gao, Li

AU - Tang, Ning

AU - Duan, Junxi

AU - Mei, Fuhong

AU - Meng, Hu

AU - Lu, Fangchao

AU - Xu, Fujun

AU - Wang, Xinqiang

AU - Yang, Xuelin

AU - Ge, Weikun

AU - Shen, Bo

PY - 2014/6/16

Y1 - 2014/6/16

N2 - To explore the transport properties of polycrystalline graphene under large tensile strain, a strain device has been fabricated using piezocrystal to load local strain onto graphene, up to 22.5%. Ionic liquid gate whose capability of tuning carrier density being much higher than that of a solid gate is used to survey the transfer characteristics of the deformed graphene. The conductance of the Dirac point and field effect mobility of electrons and holes is found to decrease with increasing strain, which is attributed to the scattering of the graphene grain boundaries, the strain induced change of band structure, and defects. However, the transport gap is still not opened. Our study is helpful to evaluate the application of graphene in stretchable electronics.

AB - To explore the transport properties of polycrystalline graphene under large tensile strain, a strain device has been fabricated using piezocrystal to load local strain onto graphene, up to 22.5%. Ionic liquid gate whose capability of tuning carrier density being much higher than that of a solid gate is used to survey the transfer characteristics of the deformed graphene. The conductance of the Dirac point and field effect mobility of electrons and holes is found to decrease with increasing strain, which is attributed to the scattering of the graphene grain boundaries, the strain induced change of band structure, and defects. However, the transport gap is still not opened. Our study is helpful to evaluate the application of graphene in stretchable electronics.

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SN - 0003-6951

VL - 104

JO - Applied Physics Letters

JF - Applied Physics Letters

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M1 - 243108

ER -

Electronic properties of polycrystalline graphene under large local strain

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