Title :
Capacitance estimation for InAs Tunnel FETs by means of full-quantum k·p simulation
Author :
Baravelli, E. ; Gnani, Elena ; Gnudi, A. ; Reggiani, S. ; Baccarani, G.
Author_Institution :
ARCES & DEI, Univ. of Bologna, Bologna, Italy
Abstract :
We report for the first time a quantum mechanical simulation study of gate capacitance components in aggressively scaled InAs Tunnel Field-Effect Transistor (TFET) nanowires. It will be shown that the gate-drain capacitance follows the same trend as the total gate capacitance (but with smaller values) over the whole Vgs range, hence confirming the capacitance estimation provided by semiclassical TCAD tools from a qualitative point of view. However, we find that the gate capacitance exhibits a nonmonotonic behavior as a function of the gate voltage, with plateaus and bumps, depending on the amount of energy quantization determined by the device cross-sectional size, and the position of channel-conduction subbands relative to the Fermi level in the drain contact. From this point of view, semiclassical TCAD tools seem to be inaccurate for capacitance estimation in aggressively scaled TFET devices.
Keywords :
Fermi level; field effect transistors; nanowires; tunnel transistors; Fermi level; InAs; TFET devices; bumps; capacitance estimation; channel-conduction subbands; device cross-sectional size; drain contact; energy quantization; full-quantum k·p simulation; gate capacitance components; gate voltage; gate-drain capacitance; nonmonotonic behavior; plateaus; quantum mechanical simulation study; semiclassical TCAD tools; tunnel FETs; tunnel field-effect transistor nanowires; CMOS integrated circuits; Estimation; Logic gates; MOSFET; Nanowires; Quantum capacitance; Full-quantum simulation; Tunnel Field-Fffect Transistor (TFET); parasitic capacitance;
Conference_Titel :
Ultimate Integration on Silicon (ULIS), 2014 15th International Conference on
Conference_Location :
Stockholm
DOI :
10.1109/ULIS.2014.6813895
