A. Vallett, S. Minassian, S. Datta, J. Redwing, T. Mayer
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Fabrication of axially-doped silicon nanowire tunnel FETs and characterization of tunneling current
Recent interest in low-power electronics has sparked considerable interested in gate-controlled tunneling-based transistors (TFETs), which have demonstrated inverse subthreshold slopes (S) better than the MOSFET limit of 60 mV/dec.1 While the natural progression of these devices to nanoscale dimensions promises improved performance23, there is a lack of experimental data regarding the physics of tunneling at reduced dimensions. Here we present a TFET fabricated from an individual axially-doped p+-n-n+ Si nanowire in a device layout that enables the study of tunneling physics as the wire dimensions are scaled to the 1D transport regime.
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