03207nam 2200889z- 450 991063999260332120231214133140.03-0365-6167-6(CKB)5470000001633427(oapen)https://directory.doabooks.org/handle/20.500.12854/95892(EXLCZ)99547000000163342720202301d2022 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierGraphene for ElectronicsBaselMDPI - Multidisciplinary Digital Publishing Institute20221 electronic resource (180 p.)3-0365-6168-4 Graphene is an allotrope of carbon consisting of a single layer of atoms arranged in a two-dimensional (2D) honeycomb lattice. Graphene's unique properties of thinness and conductivity have led to global research into its applications as a semiconductor. With the ability to well conduct electricity at room temperature, graphene semiconductors could easily be implemented into the existing semiconductor technologies and, in some cases, successfully compete with the traditional ones, such as silicon. This reprint presents very recent results in the physics of graphene, which can be important for applying the material in electronics.Physicsbicsscgraphenescatteringdephasingrelaxation timeband structuretight-binding modelangle-resolved photoemissionelectron scatteringaugmented plane wavesnanoscrollfirst-principleKlein tunnelingboropheneDirac fermionselectric fieldvalence charge densityimage potentialimage-plane positionimage-potential statesliquid conductorgraphene solutioncirculating systemmicrofluidic channeltemperatureoptical powerCVD graphenepolycrystallinegrain sizesingle-crystalline graingrain boundary (GB)GB distributionsheet resistancetransmission-line model measurementBose-Einstein condensationsuperfluiditydipolar exitonslow-dimensional semimetalselectronic transport in graphenequantum hall effection-selective field-effect transistorsodium ionsreal-time monitoringmechanochemistrygraphene nanosheetsconductive inkinkjet printingprinted electronicsPhysicsKogan Eugeneedt1302848Kogan EugeneothBOOK9910639992603321Graphene for Electronics3026688UNINA