Title :
Electrical overstress and electrostatic discharge
Author :
Diaz, Carlos ; Kang, S.M. ; Duvvury, Charvaka
Author_Institution :
IC Bus. Div., Hewlett-Packard Co., Palo Alto, CA, USA
fDate :
3/1/1995 12:00:00 AM
Abstract :
Semiconductor devices have a limited ability to sustain electrical overstress (EOS). The device susceptibility to EOS increases as the device is scaled down to submicron feature size. At present, EOS is a major cause for IC failures. Published reports indicate that nearly 40% of IC failures can be attributed to EOS events. Hence, EOS threats must be considered early in the design process. For semiconductor devices, EOS embodies a broad range of electrical threats due to electromagnetic pulses, electrostatic discharge (ESD), system transients, and lightning. EOS-related failures in semiconductor devices can be classified according to their primary failure mechanisms into: thermally-induced failures, electromigration, electric-field-related failures. In general, thermally-induced failures are related to the doping level, junction depth, and device characteristic-dimensions whereas electric-field induced failures are primarily related to the breakdown of thin oxides in MOS devices
Keywords :
electromagnetic pulse; electrostatic discharge; failure analysis; semiconductor device reliability; semiconductor devices; transients; IC failures; MOS devices; breakdown; design process; device characteristic-dimensions; doping level; electric-field-related failures; electrical overstress; electromagnetic pulses; electromigration; electrostatic discharge; junction depth; lightning; primary failure mechanisms; semiconductor devices; thermally-induced failures; thin oxides; transients; tutorial; Earth Observing System; Electromagnetic devices; Electromagnetic transients; Electromigration; Electrostatic discharge; Failure analysis; Lightning; Process design; Semiconductor device doping; Semiconductor devices;
Journal_Title :
Reliability, IEEE Transactions on
