F. S. Turco-Sandroff scite author profile

F. S. Turco-Sandroff

5Publications

86Citation Statements Received

0Citation Statements Given

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254

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114

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Effects of thermal strain on the optical properties of heteroepitaxial ZnTe

1992

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Optical measurements have been used to study the biaxial tensile strain in heteroepitaxial ZnTe grown by molecular-beam epitaxy on both GaAs and GaSb substrates, and its effect on the low-temperature photoluminescence (PL) spectrum of the material. The observed strain (0.92 X 10 ' for ZnTe/GaAs and 0.45X10 ' for ZnTe/GaSb) agrees with that expected for differential thermal contraction from the growth temperature to low temperature, based on the difference in thermal expansion coefficients. The amount of strain increases with growth temperature, as expected, but decreases slightly in thin layers on GaAs. The latter effect is due to incomplete relaxation of the large (7.6%%uo) lattice mismatch strain between ZnTe and GaAs, the unrelieved part of which constitutes a biaxial compressive strain. Reflectance and variable temperature PL measurements show that the free exciton splits into heavy-hole (I») and light-hole (X&h) components, which both shift to lower energy. The J =1 (allowed) and J =2 (forbidden) components of the oxygen isoelectronic center bound exciton are mixed and shifted to lower energy by the strain. Temperature-dependent PL measurements show that the oscillator strengths of the two components are strongly redistributed by the strain. We calculate the strain-induced splittings in the 0-bound exciton and in the excitons bound to neutral acceptors and neutral double acceptors, and find good agreement with the experimentally observed peak positions. Further confirmation of our assignrnents of the strain-split and shifted bound exciton peaks is obtained using magnetospectroscopy in fields up to 12 T. The diamagnetism, g factors, and splitting patterns of the free and bound excitons in the magnetic field are discussed.

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Evolution of the band gap and the dominant radiative recombination center versus the composition for ZnSe1−xTex alloys grown by molecular beam epitaxy

Brasil¹,

Nahory²,

Turco-Sandroff³

et al. 1991

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We report a systematic study of the optoelectronic properties of ZnSe1−xTex alloys grown by molecular beam epitaxy over the entire range of compositions. The band-gap energy as a function of the composition presents a minimum at x≂0.65. The main luminescence emission observed at 5 K becomes narrower and closer to the band-gap energy as we increase the Te content. The linewidth and the difference between the emission peak and band-gap energy decrease significantly with increasing x and present a break in the slope at x≂0.65.

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Surface segregation in III–V alloys

Moison¹,

Houzay²,

Barthe³

et al. 1991

Journal of Crystal Growth

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Molecular beam epitaxy of Zn(Se,Te) alloys and superlattices

Turco-Sandroff¹,

Nahory²,

Brasil³

et al. 1991

Journal of Crystal Growth

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Recombination at GaAs surfaces and GaAs/AlGaAs interfaces probed by in situ photoluminescence

Sandroff¹,

Turco-Sandroff²,

Florez³

et al. 1991

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We use in situ photoluminescence (PL) to investigate recombination at (100)GaAs surfaces and GaAs/AlGaAs interfaces in a controlled crystal growth environment. PL was monitored for different GaAs surface reconstructions, after surface chemical modification, and during early stages of AlGaAs heteroepitaxy. Depositing ∼1 ML of Se to form a (2×1) surface increased the GaAs PL intensity 200 times. Surprisingly, it required 6 ML (15 Å) of heteroepitaxial AlGaAs to achieve the same degree of surface passivation. We invoke lateral variations in interfacial AlGaAs composition to explain these results.

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