Title :
Comparative Analysis of Mechanical Strain and Silicon Film Thickness on Charge Collection Mechanisms of Nanometer Scaled SOI Devices Under Heavy Ion and Pulsed Laser Irradiation
Author :
Gaillardin, M. ; Raine, M. ; Duhamel, O. ; Girard, S. ; Paillet, P. ; McMorrow, Dale ; Warner, Jeffrey H. ; Andrieu, F. ; Barraud, S. ; Faynot, O. ; Roche, Nicholas J.-H
Author_Institution :
DAM, CEA, Arpajon, France
Abstract :
We investigate the impact of performance boosters using mechanical stress on the Single-Event Transient (SET) response of nanometer scaled Fully-Depleted Silicon-On-Insulator (SOI) devices. Laser SET measurements show that the active silicon layer thickness is the most important contributor to the SET response of highly scaled Ultra-Thin SOI (UTSOI) devices compared to the impact of strain. This is then demonstrated by dedicated TCAD calculations performed without taking into account any strain engineering technique. Finally, heavy ion-induced charge collection mechanisms are analyzed through the measurement of fast transients to get additional insights into the impact of short channel effects on the SET response of nanometer scaled SOI devices.
Keywords :
elemental semiconductors; nanoelectronics; radiation hardening (electronics); silicon; silicon-on-insulator; technology CAD (electronics); transistors; SET response; TCAD calculations; UTSOI; heavy ion-induced charge collection mechanisms; mechanical strain; nanometer scaled fully-depleted silicon-on-insulator devices; pulsed laser irradiation; short channel effects; silicon film thickness; single event transient; ultra-thin SOI devices; Lasers; Logic gates; Measurement by laser beam; Silicon; Strain; Transient analysis; Transistors; Charge collection; fully depleted (FD); heavy ion; mechanical stress; pulsed laser; silicon on insulator (SOI); single-event effects (SEE); single-event transient (SET); strained silicon; ultra-thin SOI (UTSOI);
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2014.2314143
