Title :
A simulation model for electromigration in fine-line metallization of integrated circuits due to repetitive pulsed currents
Author :
Harrison, James W.
Author_Institution :
Center for Semicond. Device Reliability Res., Clemson Univ., SC, USA
fDate :
12/1/1988 12:00:00 AM
Abstract :
The design trend of digital very-large-scale integrated circuits (VLSI) toward higher power dissipation per chip, higher switching speeds, and smaller cross-section interconnect metallization lines has increased concern about the reliability of these devices with respect to electromigration as a failure mechanism. A simulation model for the major physical processes that influence the development and progression of electromigration damage due to pulsed electric currents is described. A comparison of model behavior to that observed experimentally for steady current (DC) stressing is made, and it is concluded that the model may provide a reasonable prediction of expected behavior under pulsed current stressing. However, experimental verification of the model is required before it can be used with assurance for design guidance
Keywords :
VLSI; aluminium; aluminium alloys; copper alloys; digital integrated circuits; digital simulation; electromigration; metallisation; reliability; Al metallisation; AlCu alloy metallisation; DC stressing; VLSI; design guidance; digital very-large-scale integrated circuits; electromigration; experimental verification; failure mechanism; fine-line metallization; higher power dissipation per chip; higher switching speeds; integrated circuits; metallization lines; physical processes; pulsed current stressing; repetitive pulsed currents; simulation model; smaller cross-section interconnect; Circuit simulation; Digital integrated circuits; Electromigration; High speed integrated circuits; Metallization; Power dissipation; Predictive models; Switching circuits; Very high speed integrated circuits; Very large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
