2016
DOI: 10.3390/electronics5010003
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Simulation of 50-nm Gate Graphene Nanoribbon Transistors

Abstract: An approach to simulate the steady-state and small-signal behavior of GNR MOSFETs (graphene nanoribbon metal-semiconductor-oxide field-effect transistor) is presented. GNR material parameters and a method to account for the density of states of one-dimensional systems like GNRs are implemented in a commercial device simulator. This modified tool is used to calculate the current-voltage characteristics as well the cutoff frequency f T and the maximum frequency of oscillation f max of GNR MOSFETs. Exemplarily, w… Show more

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Cited by 31 publications
(13 citation statements)
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“…In the present work, we follow a different approach and use a classical device simulator for the investigation of GNR MOSFETs. To this end, an approach to account for the density of states in one‐dimensional systems like GNRs by properly adjusting the carrier effective mass m eff has been elaborated . Together with the v ‐ E characteristics according to equation with the parameters from Table , this approach has been implemented in the commercial device simulator ATLAS.…”
Section: Gnr Mosfetsmentioning
confidence: 99%
“…In the present work, we follow a different approach and use a classical device simulator for the investigation of GNR MOSFETs. To this end, an approach to account for the density of states in one‐dimensional systems like GNRs by properly adjusting the carrier effective mass m eff has been elaborated . Together with the v ‐ E characteristics according to equation with the parameters from Table , this approach has been implemented in the commercial device simulator ATLAS.…”
Section: Gnr Mosfetsmentioning
confidence: 99%
“…This Special Issue comprises a total of 12 papers (four review papers and eight contributed articles) and spans a wide range of topics, which extend from first principle band structure calculations [14] and molecular dynamics simulations of the thermal properties [15] of 2D materials, over numerical simulations and compact modeling of 2D transistors [16][17][18] and other 2D devices [19,20], 2D material growth [21,22] and processing issues [22][23][24], up to experimental 2D devices and their applications [22,23,25]. Regarding the materials, the papers of the Special Issue deal with graphene and graphene nanoribbons [16][17][18][19][20]22,23,25], TMDs (transition metal dichalcogenide) [14,21,22,24,25], phosphorene, which frequently is called 2D black phosphorus [24,25], and 2D metal oxides [25].…”
Section: The Present Special Issuementioning
confidence: 99%
“…Regarding the materials, the papers of the Special Issue deal with graphene and graphene nanoribbons [16][17][18][19][20]22,23,25], TMDs (transition metal dichalcogenide) [14,21,22,24,25], phosphorene, which frequently is called 2D black phosphorus [24,25], and 2D metal oxides [25]. Finally, the papers discuss More Moore electronics and transistors [16][17][18], as well as applications belonging to the More Than Moore domain of semiconductor electronics, including optoelectronics [22], RF electronics [16,23], sensors [20,25], and field emitters [19].…”
Section: The Present Special Issuementioning
confidence: 99%
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“…So far, there are no device simulation tools available to analyse and assess the device characteristics with 2D channel materials. Many attempts have been made to build a new simulation tool that incorporates the transport mechanism of 2D materials with reduced computational cost [16][17][18]. Hence, the need for a sophisticated method with reduced computational cost with better accuracy has aroused for accurate modelling of 2D material devices.…”
Section: Introductionmentioning
confidence: 99%