Title :
Cell endurance prediction from a large-area SONOS capacitor
Author :
Lee, C.H. ; Tu, W.H. ; Gu, S.H. ; Wu, C.W. ; Lin, S.W. ; Yeh, T.H. ; Chen, K.F. ; Chen, Y.J. ; Hsieh, J.Y. ; Huang, I.J. ; Zous, N.K. ; Han, T.T. ; Chen, M.S. ; Lu, W.P. ; Chen, K.C. ; Wang, Tahui ; Lu, C.Y.
Author_Institution :
Macronix Int. Co., Ltd., Hsinchu, Taiwan
Abstract :
Endurance considerations induced by the degradation of top and bottom oxides are proposed for a SONOS memory. First, a correlation is found between the widespread C-V curves induced by interface generation and cycling numbers (cyc. #). Unlike VFB (accumulation region), VT (inversion region) shows a much severe shift. Interface state (Nit) is identified as a key factor even when a 2 nm bottom oxide is used. Moreover, charge to breakdown (QBD) for an ONO capacitor under positive and negative constant current stress (CCS) is investigated. Our study reveals that QBD of such stacks strongly depends on the top oxide thickness. A field enhancement induced by charges in a trapping nitride layer is the root cause. Based on Weibull statistics, the risk of dielectric breakdown for both blocking layers is then evaluated.
Keywords :
capacitors; electric breakdown; statistical analysis; stress analysis; SONOS memory; Weibull statistics; cell endurance prediction; cycling numbers; dielectric breakdown; field enhancement; interface generation; interface state; large-area SONOS capacitor; negative constant current stress; size 2 nm; Capacitance-voltage characteristics; Capacitors; Carbon capture and storage; Degradation; Dielectric breakdown; Electric breakdown; Interface states; SONOS devices; Statistics; Stress;
Conference_Titel :
Reliability Physics Symposium, 2009 IEEE International
Conference_Location :
Montreal, QC
Print_ISBN :
978-1-4244-2888-5
Electronic_ISBN :
1541-7026
DOI :
10.1109/IRPS.2009.5173373
