Title :
Scaling of thermal stresses in passivated nano-interconnects
Author :
Sharma, P. ; Ganti, S. ; Ardebili, H. ; Alizadeh, A.
Author_Institution :
Dept. of Mech. Eng., Houston Univ., TX, USA
Abstract :
Much work has been done in the approximation of the stress state of microelectronics interconnects-on-chips. The thermally induced stresses in passivated interconnects are of interest as they are used as input in interconnect reliability failure models (stress-driven void growth, electromigration driven void growth). The typically used classical continuum mechanics and physics is, however, intrinsically size-independent. This is in contradiction to the physical fact that at the size-scale of a few nanometers, the elastic state is size-dependent and a departure from classical mechanics is expected. In this work, we address the various physical causes (and the affiliated mathematical modeling) of the size-dependency of mechanical stresses in nano-interconnects. In essence, we present scaling laws for mechanical stresses valid for nano-sized interconnect.
Keywords :
continuum mechanics; elasticity; electromigration; failure analysis; integrated circuit interconnections; integrated circuit modelling; integrated circuit reliability; internal stresses; passivation; semiconductor process modelling; thermal stresses; voids (solid); classical mechanics; continuum mechanics; elastic state; electromigration; interconnect reliability failure models; mechanical stresses; microelectronics interconnects-on-chips; nanointerconnects; nanosized interconnect; passivated interconnects; scaling laws; thermal stresses; void growth; Electromigration; Fabrication; Mathematical model; Mechanical engineering; Microelectronics; Moore´s Law; Passivation; Physics; Temperature; Thermal stresses;
Conference_Titel :
Thermal and Thermomechanical Phenomena in Electronic Systems, 2004. ITHERM '04. The Ninth Intersociety Conference on
Print_ISBN :
0-7803-8357-5
DOI :
10.1109/ITHERM.2004.1318315
