Title :
Statistical model for radiation-induced wear-out of ultra-thin gate oxides after exposure to heavy ion irradiation
Author :
Cester, Andrea ; Cimino, Salvatore ; Miranda, Enrique ; Candelori, Andrea ; Ghidini, Gabriella ; Paccagnella, Alessandro
Author_Institution :
Dipt. di Ingegneria dell´´Informazione, Univ. di Padova, Italy
Abstract :
In this work, we present an original model to explain the accelerated wear-out behavior of irradiated ultra-thin oxides. The model uses a statistical approach to the breakdown occurrences based on a nonhomogeneous Poisson process. By means of our model, we can estimate the number and the time evolution of those damaged regions produced by ion hits that generate breakdown spots during high field stresses after irradiation, including the dependence on the oxide field. Also, by using the proposed model, we have studied the wear-out dependence on the stress voltage, gate area, and ion fluence. In particular, by studying the stress voltage dependence of wear-out acceleration, it is feasible to extrapolate the device lifetime even at low operating voltage.
Keywords :
CMOS integrated circuits; insulating thin films; integrated circuit reliability; ion beam effects; radiation hardening (electronics); semiconductor device breakdown; stochastic processes; breakdown occurrences; damaged regions; device lifetime; gate area; heavy ion irradiation; high field stresses; ion fluence; low operating voltage; nonhomogeneous Poisson process; radiation-induced wear-out; statistical approach; statistical model; stress voltage; stress voltage dependence; time evolution; ultra-thin gate oxides; wear-out acceleration; wear-out dependence; Acceleration; Breakdown voltage; CMOS technology; Circuits; Degradation; Electric breakdown; Electrons; Leakage current; Microelectronics; Stress;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2003.821606
