Title :
Hot-carrier degradation modeling using full-band Monte-Carlo simulations
Author :
Tyaginov, S.E. ; Starkov, I.A. ; Triebl, O. ; Cervenka, J. ; Jungemann, C. ; Carniello, S. ; Park, J.M. ; Enichlmair, H. ; Karner, M. ; Kernstock, Ch ; Seebacher, E. ; Minixhofer, R. ; Ceric, H. ; Grasser, T.
Author_Institution :
Inst. for Microelectron., Tech. Univ. Wien, Vienna, Austria
Abstract :
We propose and verify a model for hot carrier degradation based on the exhaustive evaluation of the energy distribution function for charge carriers in the channel by means of a full-band Monte-Carlo device simulator. This approach allows us to capture the interplay between “hot” and “colder” electrons and their contribution to the damage build-up. In fact, particles characterized by higher energy are able to produce interface traps by a single-carrier process while colder ones trigger multivibrational mode excitation of a Si-H bond. For the model validation we use long-channel MOSFETs and represent the degradation of the linear drain current. The single-carrier component dominates degradation (this is the usual tendency for long devices), however, the multiple-carrier process is still considerable being less and less pronounced as the source-drain stress voltage increases.
Keywords :
MOSFET; Monte Carlo methods; hot carriers; semiconductor device models; charge carriers; energy distribution function; exhaustive evaluation; full-band Monte-Carlo simulations; hot-carrier degradation modeling; linear drain current; long-channel MOSFET; multivibrational mode excitation; Bonding; Charge carriers; Degradation; Distribution functions; Hot carriers; Interface states; MOSFETs; Microelectronics; Stress; Voltage;
Conference_Titel :
Physical and Failure Analysis of Integrated Circuits (IPFA), 2010 17th IEEE International Symposium on the
Conference_Location :
Singapore
Print_ISBN :
978-1-4244-5596-6
DOI :
10.1109/IPFA.2010.5532001
