Title :
A physics-based model of the dielectric breakdown in HfO2 for statistical reliability prediction
Author :
Vandelli, Luca ; Padovani, Andrea ; Larcher, Luca ; Bersuker, Gennadi ; Yum, Jung ; Pavan, Paolo
Author_Institution :
DISMI (Dipt. di Sci. e Metodi dell´´Ing.), Univ. di Modena e Reggio Emilia, Modena, Italy
Abstract :
We present a quantitative physical model describing the current evolution due to the formation of a conductive filament responsible for the HfO2 dielectric breakdown. By linking the microscopic properties of the stress-generated electrical defects to the local power dissipation and to the corresponding temperature increase along the conductive path the model reproduces the rapid current increase observed during the breakdown. The model successfully simulates the experimental time-dependent dielectric breakdown distributions measured in HfO2 MIM capacitors under constant voltage stress, thus providing a statistical reliability prediction capability, which can be extended to other high-k materials, multilayer stacks, resistive memories based on transition metal oxides, etc.
Keywords :
MIM devices; capacitors; electric breakdown; hafnium compounds; reliability; statistical analysis; HfO2; MIM capacitors; conductive filament; constant voltage stress; high-k materials; multilayer stacks; power dissipation; quantitative physical model; resistive memories; statistical reliability prediction; stress-generated electrical defects; time-dependent dielectric breakdown distributions; transition metal oxides; Dielectrics; Electric breakdown; Electron traps; High K dielectric materials; Logic gates; Power dissipation; Tin; HfO2; RRAM; TDDB; breakdown statistics; dielectric breakdown; forming; high-k;
Conference_Titel :
Reliability Physics Symposium (IRPS), 2011 IEEE International
Conference_Location :
Monterey, CA
Print_ISBN :
978-1-4244-9113-1
Electronic_ISBN :
1541-7026
DOI :
10.1109/IRPS.2011.5784582
