D. Pawlik, M. Barth, P. Thomas, S. Kurinec, S. Mookerjea, D. Mohata, S. Datta, S. Cohen, D. Ritter, S. Rommel
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引用次数: 12
Abstract
Tunneling field effect transistors (TFET), which are gated Esaki tunnel junctions (ETD) operating in the Zener regime, have theoretically been predicted to operate with ultra low power supplies (<0.5 V) and steep subthreshold slopes (<60 mV/dec) [1, 2]. However, the majority of these projections have been made based on uncalibrated TCAD modeling. To this end, the authors experimentally demonstrate a pair of InGaAs tunnel diodes with the highest peak current densities (JP = IP/Area) ever reported for tunnel diodes (975 kA/cm2 or 9.75 mA/µm2) [3–5]. Other groups have attempted to experimentally demonstrate these structures, but were limited by a combination of output current and series resistance [6]. The key innovation in this study was a process for testing deep submicron Esaki diodes [7], which mitigates these factors.
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