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Faster in-plane switching and reduced rotational viscosity characteristics in a graphene-nematic suspension.

Authors :
Basu, Rajratan
Kinnamon, Daniel
Skaggs, Nicole
Womack, James
Source :
Journal of Applied Physics; 5/14/2016, Vol. 119 Issue 18, p185107-1-185107-7, 7p, 1 Diagram, 5 Graphs
Publication Year :
2016

Abstract

The in-plane switching (IPS) for a nematic liquid crystal (LC) was found to be considerably faster when the LC was doped with dilute concentrations of monolayer graphene flakes. Additional studies revealed that the presence of graphene reduced the rotational viscosity of the LC, permitting the nematic director to respond quicker in IPS mode on turning the electric field on. The studies were carried out with several graphene concentrations in the LC, and the experimental results coherently suggest that there exists an optimal concentration of graphene, allowing a reduction in the IPS response time and rotational viscosity in the LC. Above this optimal graphene concentration, the rotational viscosity was found to increase, and consequently, the LC no longer switched faster in IPS mode. The presence of graphene suspension was also found to decrease the LC's pretilt angle significantly due to the π-π electron stacking between the LC molecules and graphene flakes. To understand the π-π stacking interaction, the anchoring mechanism of the LC on a CVD grown monolayer graphene film on copper substrate was studied by reflected crossed polarized microscopy. Optical microphotographs revealed that the LC alignment direction depended on monolayer graphene's hexagonal crystal structure and its orientation. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00218979
Volume :
119
Issue :
18
Database :
Complementary Index
Journal :
Journal of Applied Physics
Publication Type :
Academic Journal
Accession number :
115352390
Full Text :
https://doi.org/10.1063/1.4949481