ISSN:
1089-7550
Source:
AIP Digital Archive
Topics:
Physics
Notes:
Long and middle wavelength infrared (LWIR, MWIR) p+-n photodiodes have been fabricated with Hg1−xCdxTe (0.20〈x〈0.30) grown by molecular-beam epitaxy (MBE). The epilayers were grown on (211)B lattice-matched ZnCdTe substrates. The surface morphology was smooth and free of in-plane twins. The Cd concentration (x) was uniform across the wafer, with standard deviations (Δx) as low as 0.0017. Structural properties were measured by double-crystal x-ray rocking curve and dislocation etching; FWHM values as low as 34 arcsec and etch pit density values as low as 1×105 cm−2 were measured. p+ -n homojunctions were formed by arsenic diffusion; unpassivated mesa photodiodes were fabricated by standard photolithographic techniques. MWIR and LWIR photodiodes fabricated with MBE material exhibited good diode performance, comparable to that obtained on photodiodes fabricated with the more matured technique of liquid-phase epitaxy. 77-K R0A products of the diodes measured were 6.35×107, 22.3, and 1.76 Ω cm2 with cutoff wavelengths of 4.66, 9.96, and 12.90 μm, respectively. The R0A product for a VLWIR photodiode was 1.36×102 Ω cm2 with a cutoff wavelength of 16.23 μm at 35 K. LWIR diodes with no antireflection coating had a quantum efficiency of 48.6%. The present results represent a significant step toward the demonstration of MBE as a viable growth technique for the fabrication of large infrared focal plane arrays.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1063/1.342925
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