Title :
The physical mechanisms of IG Random Telegraph Noise in deeply scaled pMOSFETs
Author :
Ji, Xiaodong ; Liao, Yifan ; Zhu, C. ; Chang, Joana ; Yan, Fengping ; Shi, Y. ; Guo, Qinglai
Author_Institution :
Sch. of Electron. Sci. & Eng., Nanjing Univ., Nanjing, China
Abstract :
The physical mechanism of IG Random Telegraph Noise (IG-RTN) has been studied in deeply scaled pMOSFETs subject to Negative Bias Temperature Stress (NBTS). Using carrier separation technique, we identify the majority carriers in IG-RTN are channel holes. By investigating the electric field and temperature dependence of the capture time τc and emission time τe in IG-RTN, it is found that the physical origin of IG-RTN are NBTS-induced switching traps; Further quantitative analysis of IG-VG reveal that IG-RTN is related to a tunneling process. Based on these results, we propose a tunneling model through NBTS-induced switching traps to explain the discrete gate leakage. The model provides a good agreement between the predicted and experimental data.
Keywords :
MOSFET; electrical faults; negative bias temperature instability; semiconductor device noise; semiconductor device reliability; IG random telegraph noise; capture time; carrier separation technique; channel holes; deeply scaled pMOSFET; discrete gate leakage; electric field; emission time; negative bias temperature stress; physical mechanisms; temperature dependence; Fitting; Leakage currents; Logic gates; MOSFET; Stress; Switches; Tunneling; Carrier Separation; IG-RTN; Negative Bias Temperature Stress; Switching trap; Trap Assisted Tunneling;
Conference_Titel :
Reliability Physics Symposium (IRPS), 2013 IEEE International
Conference_Location :
Anaheim, CA
Print_ISBN :
978-1-4799-0112-8
Electronic_ISBN :
1541-7026
DOI :
10.1109/IRPS.2013.6532122
