In-situ reflectance monitoring during MOCVD of AlGaN

Ng, T.B.; Han, Jung; Biefeld, R. M.; Weckwerth, M.V.

doi:10.1007/s11664-998-0385-8

Cited by 44 publications

(20 citation statements)

References 22 publications

(15 reference statements)

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“…The deterioration of morphology at this stage is correlated with decay in in situ optical reflectance signal, suggesting that surface roughening on a scale of optical wavelength has occurred. 13 Previous studies 5,14,15 of AlGaN growth on sapphire or Si ͑111͒ substrates have shown that the compressive strain is effectively relaxed through the inclination of preexisting dislocations ͑5 ϫ 10 9 -3ϫ 10 10 cm −2 ͒; good agreement was obtained based on an analytical model ͑ av = bh tan͑͒ / 4, with av the average relaxation, b the Burgers vector, h the film thickness, the dislocation density, and the dislocation inclination angle͒.…”

Section: 5mentioning

confidence: 92%

Heteroepitaxy of AlGaN on bulk AlN substrates for deep ultraviolet light emitting diodes

Ren

Sun

Kwon

et al. 2007

Applied Physics Letters

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The authors report the growth of AlGaN epilayers and deep ultraviolet (UV) light emitting diodes (LEDs) on bulk AlN substrates. Heteroepitaxial nucleation and strain relaxation are studied through controlled growth interruptions. Due to a low density of preexisting dislocations in bulk AlN, the compressive strain during AlGaN heteroepitaxy cannot be relieved effectively. The built-up of strain energy eventually induces either an elastic surface roughening or plastic deformation via generation and inclination of dislocations, depending on the stressor interlayers and growth parameters used. AlGaN LEDs on bulk AlN exhibit noticeable improvements in performance over those on sapphire, pointing to a promising substrate platform for III-nitride UV optoelectronics.

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Section: 5mentioning

confidence: 92%

Heteroepitaxy of AlGaN on bulk AlN substrates for deep ultraviolet light emitting diodes

Ren

Sun

Kwon

et al. 2007

Applied Physics Letters

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“…We also simultaneously obtain information on the surface roughness and film thickness during deposition by monitoring the intensity of one of the reflected laser beams, similar to the method described in Ref. [19]. Figure 3 shows the stress-thickness product (σ f h f ) and the reflected beam intensity as functions of growth time (see the following explanation) during growth of an AlGaN (Al~15%) layer on a 0.6 µm GaN layer grown at 1050°C.…”

Section: Methodsmentioning

confidence: 99%

“…Figure 3 shows the stress-thickness product (σ f h f ) and the reflected beam intensity as functions of growth time (see the following explanation) during growth of an AlGaN (Al~15%) layer on a 0.6 µm GaN layer grown at 1050°C. We have reported that [19] in-situ reflectance could provide the information of growth rate from the periodicity of Fabry-Perot interference. Such information in turn enables the conversion of time axis into film thickness (h f ).…”

Section: Methodsmentioning

confidence: 99%

Monitoring and Controlling of Strain During MOCVD of AlGaN for UV Optoelectronics

Han

Crawford

Shul

et al. 1999

MRS Internet j. nitride semicond. res.

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The grown-in tensile strain, due to a lattice mismatch between AlGaN and GaN, is responsible for the observed cracking that seriously limits the feasibility of nitride-based ultraviolet (UV) emitters. We report in-situ monitoring of strain/stress during MOCVD of AlGaN based on a wafer-curvature measurement technique. The strain/stress measurement confirms the presence of tensile strain during growth of AlGaN pseudomorphically on a thick GaN layer. Further growth leads to the onset of stress relief through crack generation. We find that the growth of AlGaN directly on low-temperature (LT) GaN or AlN buffer layers results in a reduced and possibly controllable strain.

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“…The MOCVD GaN films were grown with (0001) orientation and thicknesses in the range 1.4-2.3 µm as discussed elsewhere [6]. The nominally undoped material was of n-type with a free-carrier density of ~10 17 cm -3 as determined by conductivity and Hall-effect measurements.…”

Section: Methodsmentioning

confidence: 99%

The Behavior of Ion-Implanted Hydrogen in Gallium Nitride

Myers

Headley

Hills

et al. 1999

MRS Internet j. nitride semicond. res.

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Hydrogen was ion-implanted into wurtzite-phase GaN, and its transport, bound states, and microstructural effects during annealing up to 980ºC were investigated by nuclear-reaction profiling, ion-channeling analysis, transmission electron microscopy, and infrared (IR) vibrational spectroscopy. At implanted concentrations ∨1 at.%, faceted H 2 bubbles formed, enabling identification of energetically preferred surfaces, examination of passivating N-H states on these surfaces, and determination of the diffusivity-solubility product of the H. Additionally, the formation and evolution of point and extended defects arising from implantation and bubble formation were characterized. At implanted H concentrations ∧0.1 at.%, bubble formation was not observed, and ion-channeling analysis indicated a defect-related H site located within the [0001] channel.

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In-situ reflectance monitoring during MOCVD of AlGaN

Cited by 44 publications

References 22 publications

Heteroepitaxy of AlGaN on bulk AlN substrates for deep ultraviolet light emitting diodes

Heteroepitaxy of AlGaN on bulk AlN substrates for deep ultraviolet light emitting diodes

Monitoring and Controlling of Strain During MOCVD of AlGaN for UV Optoelectronics

The Behavior of Ion-Implanted Hydrogen in Gallium Nitride

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