Dopant pockets in combination with a III-V heterostructure have become a staple in simulations of tunnel field-effect transistors (TFET) to achieve acceptable on-currents (ION) and to break the ION-subthreshold swing (SS) trade-off in pTFETs. Questions on the scalability and variability of these dopant pockets remain, however. We therefore propose an alternative concept using two opposite sheet charges at the tunnel junction that are realized by exploiting different bonding types. With fully quantum mechanical 30-band k.p-based simulations, we investigate two configurations that exhibit such sheet charges both at the device level and in a ring-oscillator: a lattice-matched GaAs-Ge-GaAs heterostructure TFET and a homostructure InGaAs TFET. By comparing to pocketed broken gap GaSb-InAs TFETs, we show that built-in sheet charge is a valid alternative for both nTFET and pTFET, with the prospect of lower variability and better scalability.
Verreck, D, Verhulst, AS, Xiang, Y, Yakimets, D, El Kazzi, S, Parvais, B, Groeseneken, G, Collaert, N & Mocuta, A 2018, 'Built-in sheet charge as an alternative to dopant pockets in tunnel field-effect transistors', IEEE Journal of the Electron Devices Society, vol. 6, pp. 658-663. https://doi.org/10.1109/JEDS.2018.2835501
Verreck, D., Verhulst, A. S., Xiang, Y., Yakimets, D., El Kazzi, S., Parvais, B., Groeseneken, G., Collaert, N., & Mocuta, A. (2018). Built-in sheet charge as an alternative to dopant pockets in tunnel field-effect transistors. IEEE Journal of the Electron Devices Society, 6, 658-663. https://doi.org/10.1109/JEDS.2018.2835501
@article{e7d0485662e34da1a52399b7087044df,
title = "Built-in sheet charge as an alternative to dopant pockets in tunnel field-effect transistors",
abstract = "Dopant pockets in combination with a III-V heterostructure have become a staple in simulations of tunnel field-effect transistors (TFET) to achieve acceptable on-currents (ION) and to break the ION-subthreshold swing (SS) trade-off in pTFETs. Questions on the scalability and variability of these dopant pockets remain, however. We therefore propose an alternative concept using two opposite sheet charges at the tunnel junction that are realized by exploiting different bonding types. With fully quantum mechanical 30-band k.p-based simulations, we investigate two configurations that exhibit such sheet charges both at the device level and in a ring-oscillator: a lattice-matched GaAs-Ge-GaAs heterostructure TFET and a homostructure InGaAs TFET. By comparing to pocketed broken gap GaSb-InAs TFETs, we show that built-in sheet charge is a valid alternative for both nTFET and pTFET, with the prospect of lower variability and better scalability.",
keywords = "Heterostructures, TFET, tunnel transistors",
author = "Devin Verreck and Verhulst, {Anne S.} and Yang Xiang and Dmitry Yakimets and {El Kazzi}, Salim and Bertrand Parvais and Guido Groeseneken and Nadine Collaert and Anda Mocuta",
year = "2018",
month = may,
day = "11",
doi = "10.1109/JEDS.2018.2835501",
language = "English",
volume = "6",
pages = "658--663",
journal = "IEEE Journal of the Electron Devices Society",
issn = "2168-6734",
publisher = "Institute of Electrical and Electronics Engineers",
}