&lt;title&gt;Liquid phase epitaxy centrifuge for growth of ultrapure gallium arsenide for far-infrared photoconductors&lt;/title&gt;

Katterloher, R.; Jakob, Gerd; Konuma, M.; Krabbe, A.; Haegel, N. M.; Samperi, S. A.; Beeman, J. W.; Häller, E. E.

doi:10.1117/12.455132

Cited by 8 publications

(1 citation statement)

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“…Katterloher and coworkers developed an LPE-grown GaAs photoconductor doped with tellurium (GaAs:Te) in order to make accurate astronomical observations. [10][11][12][13][14][15] However, this photoconductor has not yet been used for making actual observations. Cardozo et al attempted to fabricate the blocked-impurity-band (BIB) structure of a GaAs:Te photoconductor, and they investigated the far-infrared absorption coefficient of the Te donors in GaAs.…”

Section: Introductionmentioning

confidence: 97%

GaAs:Se and GaAs:Te Photoconductive Detectors in 300 µm Region for Astronomical Observations

Watanabe

Ueno

Wakaki

et al. 2008

jjap

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The wavelength region ¼ 200 { 300 mm is a little-known spectral window in observational astronomy. Recently, satelliteborne observatories, which are unaffected by atmospheric absorption and emission, have become available for astronomical research; however, the detector technology for this wavelength region is still undeveloped. N-type gallium arsenide is a good candidate for use in a high-sensitivity extrinsic photoconductor in this wavelength region. However, extrinsic photoconductors require very pure GaAs single crystals to achieve high performance. Liquid phase epitaxy is a suitable crystal growth method for realizing such pure GaAs crystals for use in fabricating the photoconductor because of the sufficient purity of the grown GaAs crystals and the considerable thickness were made possible by this method. We have GaAs doped with selenium and tellurium for fabricating the extrinsic photoconductors by the liquid phase epitaxy. By controlling the doping quantity, lightly doped GaAs:Te and GaAs:Se were successfully obtained (net donor concentrations of N D % 10 14 cm À3 ). The fabricated GaAs extrinsic photoconductors exhibited different spectral responses because of their different doping materials. The spectroscopic measurements of the GaAs photoconductors showed that they are sensitive over a wide wavelength range of 170 -320 mm. The GaAs:Te and GaAs:Se that we developed have almost the same or higher sensitivities than GaAs photoconductors developed in the past or semiconductor-based bolometers operating at T ¼ 1:6 K. Moreover, they are sensitive in a wider wavelength region than Ge:Ga photoconductors.

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