Thin- and ultra-thin-film SOI MOSFET's are promising candidates to overcome the constraints for future miniaturized devices. This paper presents simulation results for a 0.1 µm gate length SOI MOSFET structure using a two-dimensional/two-carrier device simulator with a nonlocal model for the avalanche induced carrier generation. For the suppression of punchthrough effect in devices with a channel doping of 1 1016 cm-3 and 5 nm thick gate oxide it is found that the SOI layer thickness has to be reduced to at least 20 nm. The thickness of the buried oxide should not be smaller than 50 nm in order to avoid the degradation of thin SOI performance advantages. Investigating ways to suppress the degradation of the sub-threshold slope factor at these device dimensions it was found in contrast to the common expectation that the S-factor can be improved by increasing the body doping concentration. This phenomenon, which is a unique feature of thin-film depleted SOI MOSFET's, is explained by an analytical mode. At lower doping the area of the current flow is reduced by a decreasing effective channel thickness resulting in a slope factor degradation. Other approaches for S-factor improvement are the reduction of the channel edge capacitances by source/drain engineering or the decrease of SOI thickness or gate oxide thickness. For the latter approach a higher permittivity gate insulating material should be used in order to prevent tunnelling. The low breakdown voltage can be increased by utilizing an LDD structure to be suitable for a 1.5 V power supply. However, this is at the expense of reduced current drive. An alternative could be the supply voltage reduction to 1.0 V for single drain structure use. A dual-gated SOI MOSFET has an improved performance due to the parallel combination of two MOSFET's in this device. A slightly reduced breakdown voltage indicates a larger drain electric field present in this structure.

The stability of a high-resistivity load SRAM cell using thin-film SOI MOSFET's was investigated as compared with bulk-Si MOSFET's. In SOI MOSFET's back-gate-bias effect was suppressed by indirect application of back-gate-bias to the channel region through the thick buried oxide. The Vt shifts were reduced to be 10% and 14% of that in bulk-Si MOSFET's in partially and fully depleted devices, respectively. The reduction of back-gate-bias effect provides improvement of "high" output voltage and gain in the enhancement-enhancement (EE) inverter in a high-resistivity load SRAM cell, thereby offering improved cell stability. It was demonstrated by using partially depleted SOI SRAM cells that non-destructive reading was obtained even at a low drain voltage of 1.4 V without gate-potential boost, which was much smaller than the operation limit in a bulk Si SRAM with the same patterns and dimensions used as a reference. This implies that SOI devices can also offer low-voltage operation even in TFT-load cells used in up-to-date high-density SRAM's. These results suggest that thin-film SOI MOSFET's have a superior potential of low-voltage operation expected for further scaled devices and/or for portable systems in a forthcoming multimedia era.