In this paper, the total ionizing dose (TID) response of a commercial 28-nm high-k CMOS technology at ultrahigh doses is measured and discussed. The degradation of pMOSFETs depends not only on the channel width but also on the channel length. Short-channel pMOSFETs exhibit a higher TID tolerance compared to long ones. We attributed this effect to the presence of the halo implantations. For short-channel lengths, the drain halo can overlap the source one, increasing the average bulk doping along the channel. The higher bulk doping attenuates the radiation-induced degradation, improving the TID tolerance of short-channel transistors. The results are finally compared and discussed through technology computer-aided design simulations.
Bonaldo, S., Mattiazzo, S., Enz, C., Baschirotto, A., Paccagnella, A., Jin, X., et al. (2019). Influence of Halo Implantations on the Total Ionizing Dose Response of 28-nm pMOSFETs Irradiated to Ultrahigh Doses. IEEE TRANSACTIONS ON NUCLEAR SCIENCE, 66(1), 82-90 [10.1109/TNS.2018.2876943].
Influence of Halo Implantations on the Total Ionizing Dose Response of 28-nm pMOSFETs Irradiated to Ultrahigh Doses
Baschirotto A.;
2019
Abstract
In this paper, the total ionizing dose (TID) response of a commercial 28-nm high-k CMOS technology at ultrahigh doses is measured and discussed. The degradation of pMOSFETs depends not only on the channel width but also on the channel length. Short-channel pMOSFETs exhibit a higher TID tolerance compared to long ones. We attributed this effect to the presence of the halo implantations. For short-channel lengths, the drain halo can overlap the source one, increasing the average bulk doping along the channel. The higher bulk doping attenuates the radiation-induced degradation, improving the TID tolerance of short-channel transistors. The results are finally compared and discussed through technology computer-aided design simulations.
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