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The organic functional group effect on the electronic structure of graphene nano-ribbon: A first-principles study

We report a first-principles study of the electronic structure of functionalized graphene nano-ribbon (aGNRs-f) by organic functional group (CH2C6H5) and find that CH2C6H5 functionalized group does not produce any electronic states in the gap and the band gap is direct. By changing both the density of the organic functional group and the width of the aGNRs-f, a band gap tuning exhibits a fine three family behavior through the side effect. Meanwhile, the carriers at conduction band minimum and valence band maximum are located in both CH2C6H5 and aGNR regions when the density of the CH2C6H5 is big; while they distribute dominantly in aGNR conversely. The band gap modulation effects make the aGNRs-f good candidates with high quantum efficiency and much more wavelength choices range from 750 to 93924 nm both for lasers, light emitting diodes and photo detectors due to the direct band gap and small carrier effective masses.

preprint2013arXivOpen access
Nuo LiuZheqi ZhengYongxin YaoGuiping ZhangNing LuPingjian LiCaizhuang WangKaiming Ho
cond-mat.mtrl-sci
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Nuo LiuZheqi ZhengYongxin YaoGuiping ZhangNing LuPingjian LiCaizhuang WangKaiming Ho

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