Title :
Impact of Technology Scaling in sub-100 nm nMOSFETs on Total-Dose Radiation Response and Hot-Carrier Reliability
Author :
Arora, Rajkumar ; Fleetwood, Zachary E. ; En Xia Zhang ; Lourenco, Nelson E. ; Cressler, John D. ; Fleetwood, D.M. ; Schrimpf, R.D. ; Sutton, Akil K. ; Freeman, G. ; Greene, Brian
Author_Institution :
Sch. of Electr. & Comput. Eng., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
The total-dose radiation tolerance of 32-nm nFETs is investigated. nFETs built in 32-nm RF-CMOS-on-SOI technology with high-k dielectrics show increased off-state leakage current and electron trapping in the gate oxide. The impact of CMOS-on-SOI technology scaling (from 65-nm to 32-nm) on the total-dose radiation tolerance and hot-carrier reliability (HCR) is investigated through both experiments and supporting TCAD simulations. The 32-nm nFETs exhibit less total-dose degradation compared to 45-nm nFETs. However, the hot-carrier degradation increases as the technology scales. An interplay of electric-field in the gate oxide and impact ionization in the channel region is responsible for the observed differences in the degradation mechanisms for the three technologies.
Keywords :
CMOS integrated circuits; MOSFET; dosimetry; electric fields; RF-CMOS-on-SOI technology; TCAD simulations; channel region; degradation mechanisms; electron trapping; gate oxide; hot-carrier reliability; nMOSFETs; technology scaling; total-dose degradation; total-dose radiation; total-dose radiation tolerance; Degradation; Hot carriers; Leakage currents; Logic gates; Radiation effects; Reliability; Transistors; 32-nm; 45-nm; 65-nm; BOX (buried-oxide); CMOS (complementary metal oxide semiconductor); HCR (hot carrier reliability); SOI (silicon-on-insulator); TID (total ionizing dose); nFET (field effect transistor);
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2014.2320494
