Nonradiative recombination at GaAs homointerfaces fabricated using an As cap deposition/removal process

Passlack, M.; Droopad, R.; Yu, Zhiyi; Overgaard, C.; Bowers, B.; Abrokwah, J.

doi:10.1063/1.121580

Cited by 4 publications

(2 citation statements)

References 4 publications

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“…The substrate temperature variations would affect the sticking coefficients of the As at lower temperatures. Studies have shown that the sticking coefficient is nearly exponential with temperature at these low temperatures, 8 so a 10°C variation in substrate temperature could affect the growth rates. Also, the Ascracking cell showed some instability in the As flux during growth.…”

Section: B Growth and Fabrication Of The Dbrmentioning

confidence: 99%

Very-low-temperature molecular beam epitaxial growth of GaP/AlAs heterostructures for distributed Bragg reflector applications

Pickrell

Chang

Lin

et al. 2001

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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High reflectivity and broad bandwidth AlN/GaN distributed Bragg reflectors grown by molecular-beam epitaxyGrowth and characterization of defect-free GaAs/AlAs distributed Bragg reflector mirrors on patterned InP-based heterostructures J.Using very-low-temperature ͑VLT͒ molecular beam epitaxy ͑MBE͒, ͑Ga,P͒/͑Al,As͒ heterostructures were grown for use in a distributed Bragg reflector ͑DBR͒. Through the use of VLT MBE and control of the group-V overpressure, the microstructure can be controlled resulting in either amorphous or polycrystalline material for both materials. Also, the growth rate is highly dependent on the group-V overpressure due to the high sticking coefficients of both As and P at these low growth temperatures. Using lateral oxidation, the amorphous AlAs was converted to its oxide for use in a visible wavelength DBR. Variabilities within layer thickness, especially the amorphous AlAs layers, were investigated to determine their effect on the DBR reflectivities. Different DBR designs were employed resulting in a double passband DBR which is highly reflective at wavelengths of both 550 and 1100 nm.

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Section: B Growth and Fabrication Of The Dbrmentioning

confidence: 99%

Very-low-temperature molecular beam epitaxial growth of GaP/AlAs heterostructures for distributed Bragg reflector applications

Pickrell

Chang

Lin

et al. 2001

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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“…Subsequent to epitaxial layer growth, the GaAs surface was covered by a protective arsenic cap layer. 10 After loading the wafer into another ultrahigh vacuum chamber, the As cap layer was desorbed and Ga 2 O 3 template growth commenced ͑except when no Ga 2 O 3 template was grown͒ using effusive evaporation of a polycrystalline Ga 2 O 3 source material from a high temperature effusion cell. Ga 2 O 3 template thickness ranges from 0 to 72.8 Å in this study.…”

mentioning

confidence: 99%

Role of Ga2O3 template thickness and gadolinium mole fraction in GdxGa0.4−xO0.6/Ga2O3 gate dielectric stacks on GaAs

Passlack

Medendorp

Gregory

et al. 2003

Applied Physics Letters

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Amorphous GdxGa0.4−xO0.6/Ga2O3 gate dielectric stacks have been grown onto the GaAs(001) surface by molecular beam epitaxy using high temperature effusion cells. The Ga2O3 template thickness and the Gd mole percent have been systematically varied from 73 to 0 Å and from 8.8 to 22 at. % (0.088⩽x⩽0.22), respectively. Oxide/n-type GaAs samples have been characterized by high-frequency capacitance–voltage measurements. Optimum gate oxide stack and oxide/GaAs interface properties are obtained with a Ga2O3 template thickness of 9–11 Å and a minimum Gd mole percent of 15–17 at. %. While gate oxide films with thicker Ga2O3 templates and/or lower Gd mole fraction show kinks in capacitance–voltage measurements attributed to charge trapping in the oxide, thinner Ga2O3 templates lead to strong stretch-out of capacitance–voltage curves indicating severely degraded oxide/GaAs interface properties.

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Methodology for Development of High-κ Stacked Gate Dielectrics on III–V Semiconductors

Passlack¹

Materials Fundamentals of Gate Dielectrics

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Nonradiative recombination at GaAs homointerfaces fabricated using an As cap deposition/removal process

Cited by 4 publications

References 4 publications

Very-low-temperature molecular beam epitaxial growth of GaP/AlAs heterostructures for distributed Bragg reflector applications

Very-low-temperature molecular beam epitaxial growth of GaP/AlAs heterostructures for distributed Bragg reflector applications

Role of Ga2O3 template thickness and gadolinium mole fraction in GdxGa0.4−xO0.6/Ga2O3 gate dielectric stacks on GaAs

Methodology for Development of High-κ Stacked Gate Dielectrics on III–V Semiconductors

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