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Paper detail

Complementary-like Graphene Logic Gates Controlled by Electrostatic Doping

Realization of logic circuits from graphene is very attractive for high-speed nanoelectronics. However, the intrinsic ambipolar nature hinders the formation of graphene logic devices with the conventional complementary architecture. Using electrostatic doping modulation, we show here a facile method to control the charge neutrality points and form a complementary-like structure, in which the ambipolar conduction is used as a benefit rather than a drawback to construct logic devices. A band gap is also introduced in the channels to improve the switching ratio of the graphene transistors. For the first time, complementary-like NOR and NAND logic gates were demonstrated. This method provides a possible route for logic circuits from ambipolar graphene and, in principle, can be also extended to other ambipolar semiconductors, such as organic compounds and carbon nanotube thin films.

preprint2011arXivOpen access
Song-Lin LiHisao MiyazakiMichael V. LeeChuan LiuAkinobu KandaKazuhito Tsukagoshi
cond-mat.mes-hallcond-mat.mtrl-sci
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Song-Lin LiHisao MiyazakiMichael V. LeeChuan LiuAkinobu KandaKazuhito Tsukagoshi

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