Title :
Sb-heterostructure millimeter-wave zero-bias diodes
Author :
Croke, E.T. ; Schulman, J.N. ; Chow, D.H. ; Pobanz, C. ; Case, M. ; Warren, L.D. ; Holabird, K.S. ; Dunlap, H.L. ; Haeussler, C.D.
Author_Institution :
HRL Labs., Malibu, CA, USA
Abstract :
Zero-bias, square-law detectors based on Sb-heterostructures offer a cost-effective solution for W-band imaging in large array formats. In contrast with Ge backward diodes and planar-doped barrier diodes, Sb-heterostructures have a higher frequency response and are less sensitive to process variables. Here, we demonstrate Sb-based diode detectors in the InAs/AlSb/GaAlSb material system. The large asymmetry in current flow necessary for detection arises from interband tunneling between the InAs and the GaAlSb layers. Current densities are easily controlled by varying either the Al concentration in the GaAlSb or the AlSb thickness. DC and RF characterization of these devices and an estimate of their ultimate frequency performance in comparison with commercially available diodes are presented
Keywords :
III-V semiconductors; aluminium compounds; current density; gallium compounds; indium compounds; millimetre wave detectors; millimetre wave diodes; semiconductor device measurement; semiconductor heterojunctions; stoichiometry; Al concentration; DC characterization; InAs-AlSb-GaAlSb; InAs/AlSb/GaAlSb material system; RF characterization; Sb-based diode detectors; Sb-heterostructure millimeter-wave zero-bias diodes; Sb-heterostructures; W-band imaging; asymmetry; current densities; current flow; frequency response; interband tunneling; large array formats; process variables; square-law detectors; ultimate frequency performance; Costs; Detectors; Diodes; Electrons; Frequency estimation; Frequency response; Molecular beam epitaxial growth; Radio frequency; Sensor arrays; Tunneling;
Conference_Titel :
Compound Semiconductors, 2000 IEEE International Symposium on
Conference_Location :
Monterey, CA
Print_ISBN :
0-7803-6258-6
DOI :
10.1109/ISCS.2000.947188
