Two-dimensional dynamic analysis of short-channel thin-film MOS transistors using a minicomputer

A computer program is described for simulating two-dimensional thin-film MOS transistors on a minicomputer. Data are presented showing the variation of internal carrier density with time until a steady-state condition is reached. These data show the formation of a drain-induced back channel whose conduction properties depend on the back-channel length and carrier mobility. For channel length below 2.0 µm, the two-dimensional steady-state drain current is shown to fit the expression I_{D}/W = \frac{\micro_{0}C_{0}}{L[1+(\micro_{0}/\upsilon_{s} V_{D}{L})^{2}]^{1/2}}(V_{G} - V_{T} - V_{D/2})V{D} for values of drain voltage below a specific saturation value (V_{DM}); and I_{D}/W = \frac{10^{-8)(V_{G} - V_{T})^{1/2}}{(T_{ox})^{1/2}L}.(V_{D} - V_{DM}) + I_{DM} for drain voltages above the saturation value.