Abstract
The simulation model employed in this study consists of an advanced ensemble Monte Carlo method, that incorporates two conduction energy bands from pseudopotential calculations, coupled with an interface-state genemtion model. It has been demonstrated that this coupled treatment can calculate interface-state generation with accuracy and a good overall agreement has been achieved between the simulated results and measured data in longchannel (l-pm) devices [ I]. Using the same methodology, we explored the implications of power-supply voltages driven by two widely used device-scaling approaches: field scaling [2] 'and a more generalized scaling [3]. Throughout this study, the devices are stressed for 120 seconds at Vds=2Vgs. For field scaling, we found that the simulated electron injection rates decreased from 6.4x102'/cm2sec at the location of peak electron injection for a 0.33-pin device with Vd,=3.3 V, to 2.4x10/cm2sec for a 0.12-pin device with Vd,=1.2 V. This corresponds to a predicted peak interface-state density of 7x10/cm2eV and 4.3x10/cm2eV for the 0.33-pm and 0.12-pm device, respectively. This decrease seems to be caused mainly by the reduced lateral field, (The constant lateral field methodology reduces the peak electric field from 170 kV/cm to 150 kV/cm for these short-channel devices.) On the other hand, the peak average electron energy is significantly reduced from 2.2 eV for the 0.33-pm device to 1.3 eV for the 0.12-pin device. When the generalized scaling scheme was applied, the simulated electron injection and interface-state generation rates increased considerably, from an interface-state generation density of 7x10/cm2eV for the same 0.33-pm device with Vh=3.3 V, to 9.2x10/cm2eV for a 0.12-pm device with Vd,=2.25 V. The corresponding peak electron injection rate for the 0.12-pm device was 1.1x1OZ2/cm2sec. For the generalized scaling scheme, the peak lateral field increased from 170 kV/cm to 240 kV/cm as the devices scaled down. The effect of power-supplyvoltage reduction was clearly seen in the average electron energy. The average energy at the location of pe'ak electron injection was significantly reduced, from 2.2 eV for the 0.33-pm device to 1.5 eV for the 0.12-pm device. Thus, the electron energy distribution appears to have strongly non-linear characteristics. While the average energy scales down with the power-supply voltage, the electrons in the high-energy tail of the distribution ciui bc enhanced (i.e., a longer tail) by the large peak electric field. These results for the two scaling approaches demonstrate the importance of hot electron degradation in deep-submicron MOSFETS operating below the 3 V power supply level.
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