We show that carbon nanotube Schottky-barrier transistors exhibit scaling that is qualitatively different than conventional transistors. The performance depends in an unexpected way on both the thickness and the dielectric constant of the gate oxide. Experimental measurements and theoretical calculations for ambipolar devices provide a consistent understanding of the novel scaling, which reflects the very different device physics of a Schottky-barrier transistor with a quasi-one-dimensional chan
Unexpected scaling of the performance of carbon nanotube Schottky-barrier transistors
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Carbon Nanotubes in CompositesMaterials ChemistryCarbon nanotube field-effect transistorTransconductanceScalingMaterials scienceTransistorSchottky barrierAmbipolar diffusionCarbon nanotubeSchottky diodeSubthreshold conductionSubthreshold slopeOptoelectronicsGate oxideDielectricThreshold voltageNanotubeField-effect transistorNanotechnologyVoltageDiodeElectrical engineeringPhysicsEngineering