Abstract
Defects in graphene governs electrical and optical properties. Although grain boundaries in graphene inevitably formed during large area synthesis process, which act as scattering centers for charge carriers to degrade mobility, have been studied extensively, point defects have been rarely investigated mainly due to the absence of facile observation tools. Here, we report polarized optical microscopy to observe defect distributions in monolayer graphene. This was realized by aligning liquid crystal s (LC) on graphene where the defect population was modulated by irradiating ultraviolet (UV) light directly on graphene surface under moisture condition. Aromatic rings in LC molecules are oriented with hexagonal rings in graphene to have preferred orientation, providing a way to identify relative orientations of graphene domains and point defects. Our studies show that point defects generated by prolonged UV irradiation time give rise to irregular LC alignment with disclination lines on the graphene surface and a large-size LC domain associated with graphene single domain eventually disappeared. This indicates that defects associated with oxygen-containing functional groups cause to reduce the strong stacking interaction between graphene and LC molecules.
Highlights
Indium tin oxide (ITO) with high transparency and low electric resistance has been widely used as a transparent electrode in various electronic devices such as liquid crystal display, organic light emitting diode, solar cell, and touch panel
We report polarized optical microscopy to observe defect distributions in monolayer graphene
Our studies show that point defects generated by prolonged UV irradiation time give rise to irregular liquid crystal s (LC) alignment with disclination lines on the graphene surface and a large-size LC domain associated with graphene single domain eventually disappeared
Summary
Indium tin oxide (ITO) with high transparency and low electric resistance has been widely used as a transparent electrode in various electronic devices such as liquid crystal display, organic light emitting diode, solar cell, and touch panel. Graphene can be grown ideally from a single nucleation seed, but the growth to large area is terminated by several unknown self-limiting growth factors [11,12,13,14,15] Another approach is to start with numerous nucleation seeds and allow them to grow and coalesce together to form large-area graphene. It has been reported that the GGBs of graphene surface can be visualized via an optical microscope, because the GGBs are oxidized and they are amplified after UV exposure [17] Though these methods could analyze defect sites and orientation of the graphene domains, their ability to distinguish the point defects sites is still questionable
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