Title :
Impact ionization and transport in the InAlAs/n+-InP HFET
Author :
Greenberg, David R. ; Del Alamo, Jeslis A. ; Bhat, Rajaram
Author_Institution :
MIT, Cambridge, MA, USA
fDate :
9/1/1995 12:00:00 AM
Abstract :
We have carried out an experimental study exploring both impact ionization and electron transport in InAlAs/n+-InP HFET´s. Our devices show no signature of impact ionization in the gate current, which remains below 17 μA/mm under typical bias conditions for Lg=0.8 μm devices (60 times lower than for InAlAs/InGaAs HEMT´s). The lack of impact ionization results in a drain-source breakdown voltage (BVDS) that increases as the device is turned on, displaying an off-state value of 10 V. Additionally, we find that the channel electron velocity approaches the InP saturation velocity of about 107 cm/s (in devices with Lg<1.6 μm) rather than reaching the material´s peak velocity. We attribute this to the impact of channel doping both on the steady-state peak velocity and on the conditions necessary for velocity overshoot to take place. Our findings suggest that the InP-channel HFET benefits from channel electrons which remain cold even at large VGS and VDS making the device well-suited to power applications demanding small IG, low gd, and high BVDS
Keywords :
III-V semiconductors; aluminium compounds; carrier mobility; doping profiles; impact ionisation; indium compounds; power field effect transistors; semiconductor doping; 0.8 micron; 10 V; HFET; InAlAs-InP; bias conditions; channel doping; channel electron velocity; channel electrons; drain-source breakdown voltage; electron transport; gate current; impact ionization; off-state value; power applications; steady-state peak velocity; velocity overshoot; Degradation; Electrons; HEMTs; Impact ionization; Indium compounds; Indium phosphide; MODFETs; Optical receivers; Photodiodes; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
