Title :
Two-dimensional simulation and measurement of high-performance MOSFETs made on a very thin SOI film
Author :
Yoshimi, Masato ; Hazama, Hirofumi ; Takahashi, Masaharu ; Kambayashi, S. ; Wada, Tomotaka ; Tango, H.
Author_Institution :
Toshiba Corp., Kawasaki
fDate :
3/1/1989 12:00:00 AM
Abstract :
Thinning effects on the device characteristics of silicon-on-insulator (SOI) MOSFETs are discussed. Two-dimensional/two-carrier device simulation revealed the following advantages. An n-channel MOSFET with 500-Å-SOI thickness exhibited a high-punchthrough resistance as well as an improved subthreshold swing down to a deep submicrometer region, even if the film was nearly intrinsic. A capacitance coupling model has been proposed to explain these subthreshold characteristics. The kink elimination effect, which was attributed to a significantly reduced hole density in the SOI film, was reproduced. The low-field channel mobility exhibited a significant increase, which was ascribed to a decrease in the vertical electric field. Moreover, the current-overshoot phenomenon associated with the switching operation was suppressed. Excess holes recombine with electrons quickly after the gate turn-on, bringing about a stabilized potential in the SOI substrate. Experiments were also carried out to verify the simulation
Keywords :
insulated gate field effect transistors; semiconductor device models; semiconductor-insulator boundaries; 2D simulation model; 2D two carrier simulation; 500 A; SOI MOSFETs; Si-SiO2; capacitance coupling model; current-overshoot phenomenon; device characteristics; high-punchthrough resistance; improved subthreshold swing; kink elimination effect; low-field channel mobility; n-channel MOSFET; reduced hole density; subthreshold characteristics; switching operation; thin SOI film; vertical electric field; Charge carrier processes; Circuits; Doping; Electrical resistance measurement; Helium; MOSFETs; Silicon on insulator technology; Substrates; Transconductance; Very large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
