Studies on an In0.53Ga0.47As/In0.52Al0.48As single-quantum-well quasi-MISFET

We describe here the properties of a novel InGaAs/ InAlAs quasi-MISFET in which an inverted modulation-doped single quantum well forms the channel and an undoped semi-insulating InAlAs constitutes the gate barrier. The entire structure is grown lattice-matched to InP continuously by molecular-beam epitaxy in a single step. Rapid thermal annealing of implanted semiconductors and ohmic contacts have been investigated and have been used successfully in the fabrication of the MISFET´s. Improved performance is obtained with the incorporation of Ti in the source-drain metallization, with which contact resistances as low as 0.1 ω . mm are measured. Charge-control modeling of the proposed device predicts the carrier concentration in the channel region fairly well at room temperature. A quantum mechanical modeling of the device in the effective mass approximation also has been done. The thickness of the InAlAs doping layer is found to be an important parameter that controls the device turn-on characteristics. The velocity-field characteristics of the two-dimensional channel electrons were measured by pulse current-voltage and pulsed Hall techniques. The maximum velocities measured at 300 and 77 K are 1.5 × 10⁷and 1.7 × 10⁷cm/s, respectively. Fairly high electron mobilities are measured in single-quantum-well MISFET structures even with well thicknesses as small as 100 Å. The InAlAs gate barrier is effective in reducing the gate leakage current. Gate leakage currents are reduced further with a composite dielectric consisting of oxidized Al and InAlAs. An extrinsic transconductance of 310 mS/mm is measured in a 1.0-µm gate device at 300 K. A value of fT= 32 GHz, measured in a 1.0-µm device, is the best obtained so far with this material system. It is expected that submicrometer gate lengths will lead to even better performance.