Possibilities for LWIR detectors using MBE-grown Si(/Si(1-x)Ge(x) structures
Abstract
Traditionally, long wavelength infrared (LWIR) detection in Si-based structures has involved either extrinsic Si or Si/metal Schottky barrier devices. Molecular beam epitaxially (MBE) grown Si and Si/Si(1-x)Ge(x) heterostructures offer new possibilities for LWIR detection, including sensors based on intersubband transitions as well as improved conventional devices. The improvement in doping profile control of MBE in comparison with conventional chemical vapor deposited (CVD) Si films has resulted in the successful growth of extrinsic Si:Ga, blocked impurity-band conduction detectors. These structures exhibit a highly abrupt step change in dopant profile between detecting and blocking layers which is extremely difficult or impossible to achieve through conventional epitaxial growth techniques. Through alloying Si with Ge, Schottky barrier infrared detectors are possible, with barrier height values between those involving pure Si or Ge semiconducting materials alone. For both n-type and p-type structures, strain effects can split the band edges, thereby splitting the Schottky threshold and altering the spectral response. Measurements of photoresponse of n-type Au/Si(1-x)Ge(x) Schottky barriers demonstrate this effect. For intersubband multiquntum well (MQW) LWIR detection, Si(1-x)Ge(x)/Si detectors grown on Si substrates promise comparable absorption coefficients to that of the Ga(Al)As system while in addition offering the fundamental advantage of response to normally incident light as well as the practical advantage of Si-compatibility. Researchers grew Si(1-x)Ge(x)/Si MQW structures aimed at sensitivity to IR in the 8 to 12 micron region and longer, guided by recent theoretical work. Preliminary measurements of n- and p-type Si(1-x)Ge(x)/Si MQW structures are given.
- Publication:
-
Innovative Long Wavelength Infrared Detector Workshop Proceedings
- Pub Date:
- July 1990
- Bibcode:
- 1990ilwi.work..323H
- Keywords:
-
- Germanium;
- Infrared Detectors;
- Long Wave Radiation;
- Molecular Beam Epitaxy;
- Silicon;
- Vapor Deposition;
- Absorptivity;
- Additives;
- Alloying;
- Blocking;
- Detection;
- Edges;
- Molecular Beams;
- Sensitivity;
- Spectra;
- Substrates;
- Vapors;
- Spacecraft Instrumentation