Title :
Measurement and modeling of self-heating in SOI nMOSFET´s
Author :
Su, Lisa T. ; Chung, James E. ; Antoniadis, Dimitri A. ; Goodson, Kenneth E. ; Flik, Markus I.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., MIT, Cambridge, MA, USA
fDate :
1/1/1994 12:00:00 AM
Abstract :
Self-heating in SOI nMOSFET´s is measured and modeled. Temperature rises in excess of 100 K are observed for SOI devices under static operating conditions. The measured temperature rise agrees well with the predictions of an analytical model and is a function of the silicon thickness, buried oxide thickness, and channel-metal contact separation. Under dynamic circuit conditions, the channel temperatures are much lower than predicted from the static power dissipation. This work provides the foundation for the extraction of device modeling parameters for dynamic operation (at constant temperature) from static device characterization data (where temperature varies widely). Self-heating does not greatly reduce the electromigration reliability of SOI circuits, but might influence SOI device design, e.g., requiring a thinner buried oxide layer for particular applications and scaled geometries
Keywords :
electromigration; insulated gate field effect transistors; semiconductor device models; semiconductor-insulator boundaries; silicon; SOI devices; SOI nMOSFET; analytical model; buried oxide thickness; channel temperatures; channel-metal contact separation; dynamic circuit conditions; dynamic operation; electromigration reliability; modeling; scaled geometries; self-heating; silicon thickness; static device characterization data; static operating conditions; static power dissipation; temperature rises; Cooling; Electrical resistance measurement; Integrated circuit interconnections; MOSFET circuits; Mechanical engineering; Silicon compounds; Silicon on insulator technology; Temperature measurement; Thermal conductivity; Thickness measurement;
Journal_Title :
Electron Devices, IEEE Transactions on
