Title :
Detailed characterization and analysis of the breakdown voltage in fully depleted SOI n-MOSFET´s
Author :
Kistler, Neal ; Woo, Jason
Author_Institution :
Dept. of Electr. Eng., California Univ., Los Angeles, CA, USA
fDate :
7/1/1994 12:00:00 AM
Abstract :
The breakdown voltage in fully depleted SOI n-MOSFET´s has been studied over a wide range of film thicknesses, channel dopings, and channel lengths. In lightly-doped films, the breakdown voltage roll-off at shorter channel lengths becomes much less severe as the film thickness is reduced. This is a result of improved resistance to punchthrough and DIBL effects in thinner SOI. Consequently, at channel lengths below about 0.8 μm, ultrathin (50 nm) SOI can provide better breakdown voltages than thicker films. At heavier doping levels the punchthrough and DIBL are suppressed, and there is little dependence of breakdown voltage on film thickness. Two-dimensional simulations have been used to investigate the breakdown behavior in these devices. It is found that the drain-induced barrier lowering affects the breakdown voltage both directly, via punchthrough, and indirectly through its effect on the current flow and hole generation in the high-field regions
Keywords :
carrier mobility; doping profiles; electric breakdown of solids; insulated gate field effect transistors; semiconductor device models; semiconductor-insulator boundaries; silicon; 50 nm; DIBL effects; breakdown voltage; channel dopings; channel lengths; current flow; drain-induced barrier lowering; film thicknesses; fully depleted SOI n-MOSFETs; high-field regions; hole generation; lightly-doped films; punchthrough; two-dimensional simulations; DC generators; Electric breakdown; Electrodes; MOS devices; MOSFET circuits; Oxidation; Semiconductor device doping; Silicon on insulator technology; Transconductance; Very large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
