Propriedades elétricas e vibracionais de nitretos cúbicos do grupo III / Vibrational and electrical properties of cubic group III nitrides

Fernández, José Rafael León

10 December 2001

Esta tese está dirigida ao estudo das propriedades elétricas e ópticas das camadas cúbicas de InN, GaN (intrínseco), GaN:Si (tipo-p), GaN:Si (tipo-n) e AlGaN. Por meio da técnica de efeito Hall e utilizando a configuração de Van der Pauw foram obtidas as curvas de resistividade, concentração e mobilidade em função da temperatura das camadas e através destas curvas é determinada a energia de ativação dos aceitadores e doadores. Também através das mesmas curvas são estudados os principais mecanismos que predominam no espalhamento dos portadores. Em alguns casos um comportamento anômalo foi observado (curvas de concentração e mobilidade do InN e GaN:Si (tipo-p)) e os resultados foram corrigidos utilizando-se o modelo de duas camadas e/ou modelo de duas bandas. Para o material c-InN medimos sua resistividade, concentração e mobilidade na região de baixas temperaturas para investigar um possível caráter supercondutor da amostra. Abordaremos também nesta tese o estudo teórico e experimental sobre a transição metal-semicondutor nos nitretos. Para o estudo das propriedades ópticas das camadas foi utilizada a técnica de caracterização de Raman. Por meio desta técnica e utilizando a configuração de retro espalhamento foram caracterizadas as camadas cúbicas de GaN (intrínseco), GaN:Si (tipo-p), GaN:Si (tipo-n) e AlGaN. Dos espectros, foram obtidas as posições dos picos pertencentes aos fônons transversal-ópticos (TO) e longitudinal-ópticos (LO). Verificou-se o caráter cúbico das camadas e estudou-se a origem da banda que aparece entre as posições dos modos TO e LO do material. / The thesis is devoted to the study of electrical and optical properties of cubic InN, GaN (undoped), GaN:Si (type-p), GaN:Si (type-n) and AlGaN epitaxial films. For the study of the electrical properties were measured the resistivity, concentration and mobility curves as a function of the temperature by means of Hall effect and Van der Pauw configuration technique. From these curves were obtained the activation energy of donor and acceptors levels and were studied the main dominant mechanisms for the electron scattering. In some cases an anomalous behavior of the curves was observed and was corrected using the two layer model. For the study of the superconductivity character of the cubic InN sample was measured its resistivity, concentration and mobility in the low temperature region. The thesis is also devoted to the theoretical and experimental studies of the metal-non-metal transitions in the nitrites.The optical studies of the GaN (undoped), GaN:Si (type-p), GaN:Si (type-n) and AlGaN films were done by means of Raman characterization according to a backscattering configuration. From the spectra were obtained the position of the TO and LO phonon peaks, was verified the cubic character of the films and was studied the behavior of the band found between the TO and LO phonon peaks.

Cubic nitrides

Efeito hall

Hall effect

Nitretos cúbicos

Raman

Raman

Transport

Transporte

Propriedades elétricas e vibracionais de nitretos cúbicos do grupo III / Vibrational and electrical properties of cubic group III nitrides

José Rafael León Fernández

10 December 2001

Esta tese está dirigida ao estudo das propriedades elétricas e ópticas das camadas cúbicas de InN, GaN (intrínseco), GaN:Si (tipo-p), GaN:Si (tipo-n) e AlGaN. Por meio da técnica de efeito Hall e utilizando a configuração de Van der Pauw foram obtidas as curvas de resistividade, concentração e mobilidade em função da temperatura das camadas e através destas curvas é determinada a energia de ativação dos aceitadores e doadores. Também através das mesmas curvas são estudados os principais mecanismos que predominam no espalhamento dos portadores. Em alguns casos um comportamento anômalo foi observado (curvas de concentração e mobilidade do InN e GaN:Si (tipo-p)) e os resultados foram corrigidos utilizando-se o modelo de duas camadas e/ou modelo de duas bandas. Para o material c-InN medimos sua resistividade, concentração e mobilidade na região de baixas temperaturas para investigar um possível caráter supercondutor da amostra. Abordaremos também nesta tese o estudo teórico e experimental sobre a transição metal-semicondutor nos nitretos. Para o estudo das propriedades ópticas das camadas foi utilizada a técnica de caracterização de Raman. Por meio desta técnica e utilizando a configuração de retro espalhamento foram caracterizadas as camadas cúbicas de GaN (intrínseco), GaN:Si (tipo-p), GaN:Si (tipo-n) e AlGaN. Dos espectros, foram obtidas as posições dos picos pertencentes aos fônons transversal-ópticos (TO) e longitudinal-ópticos (LO). Verificou-se o caráter cúbico das camadas e estudou-se a origem da banda que aparece entre as posições dos modos TO e LO do material. / The thesis is devoted to the study of electrical and optical properties of cubic InN, GaN (undoped), GaN:Si (type-p), GaN:Si (type-n) and AlGaN epitaxial films. For the study of the electrical properties were measured the resistivity, concentration and mobility curves as a function of the temperature by means of Hall effect and Van der Pauw configuration technique. From these curves were obtained the activation energy of donor and acceptors levels and were studied the main dominant mechanisms for the electron scattering. In some cases an anomalous behavior of the curves was observed and was corrected using the two layer model. For the study of the superconductivity character of the cubic InN sample was measured its resistivity, concentration and mobility in the low temperature region. The thesis is also devoted to the theoretical and experimental studies of the metal-non-metal transitions in the nitrites.The optical studies of the GaN (undoped), GaN:Si (type-p), GaN:Si (type-n) and AlGaN films were done by means of Raman characterization according to a backscattering configuration. From the spectra were obtained the position of the TO and LO phonon peaks, was verified the cubic character of the films and was studied the behavior of the band found between the TO and LO phonon peaks.

Efeito hall

Nitretos cúbicos

Raman

Transporte

Cubic nitrides

Hall effect

Raman

Transport

Properties of Zincblende GaN and (In,Ga,Al)N Heterostructures grown by Molecular Beam Epitaxy

Müllhäuser, Jochen R.

17 June 1999

Während über hexagonales (alpha) GaN zum ersten Mal 1932 berichtet wurde, gelang erst 1989 die Synthese einer mit Molekularstrahlepitaxie (MBE) auf 3C-SiC epitaktisch gewachsenen, metastabilen kubischen (eta) GaN Schicht. Die vorliegende Arbeit befaßt sich mit der Herstellung der Verbindungen eta-(In,Ga,Al)N mittels RF-Plasma unterstützter MBE auf GaAs(001) und den mikrostrukturellen sowie optischen Eigenschaften dieses neuartigen Materialsystems. Im Vergleich zur hexagonalen bietet die kubische Kristallstruktur auf Grund ihrer höheren Symmetrie potentielle Vorteile für die Anwendung in optischen und elektronischen Bauelementen. Viele wichtige Materialgrößen der kubischen Nitride sind jedoch noch gänzlich unbekannt, da sich die Synthese einkristalliner Schichten als sehr schwierig erweist. Das Ziel dieser Arbeit ist es daher erstens, die technologischen Grenzen der Herstellung von bauelementrelevanten kubischen (In,Ga,Al)N Heterostrukturen auszuweiten und zweitens, einen Beitrag zur Aufklärung der bis dato wenig bekannten optischen und elektronischen Eigenschaften des GaN und der Mischkristalle In GaN zu leisten. Zunächst wird ein optimierter MBE Prozess unter Einsatz einer Plasmaquelle hohen Stickstofflusses vorgestellt, welcher nicht nur die reproduzierbare Epitaxie glatter, einphasiger GaN Nukleationsschichten auf GaAs ermöglicht. Vielmehr können damit auch dicke GaN. Schichten mit glatter Oberflächenmorphologie hergestellt werden, welche die Grundlage komplizierterer eta-(In,Ga,Al)N Strukturen bilden. An einer solchen GaN Schicht mit einer mittleren Rauhigkeit von nur 1.5 nm werden dann temperaturabhängige Reflexions- und Transmissionsmessungen durchgeführt. Zur Auswertung der Daten wird ein numerisches Verfahren entwickelt, welches die Berechnung des kompletten Satzes von optischen Konstanten im Spektralgebiet 2.0 = 0.4 wären grün-gelbe Laserdioden. Zusammenfassung in PostScript / While the earliest report on wurtzite (alpha) GaN dates back to 1932, it was not until 1989 that the first epitaxial layer of metastable zincblende (eta) GaN has been synthesized by molecular beam epitaxy (MBE) on a 3C-SiC substrate. The present work focuses on radio frequency (RF) plasma-assisted MBE growth, microstructure, and optical properties of the eta-(In,Ga,Al)N material system on GaAs(001). Due to their higher crystal symmetry, these cubic nitrides are expected to be intrinsically superior for (opto-) electronic applications than the widely employed wurtzite counterparts. Owing to the difficulties of obtaining single-phase crystals, many important material constants are essentially unknown for the cubic nitrides. The aim of this work is therefore, first, to push the technological limits of synthesizing device-relevant zincblende (In,Ga,Al)N heterostructures and, second, to determine the basic optical and electronic properties of GaN as well as to investigate the hardly explored alloy InGaN. An optimized MBE growth process is presented which allows not only the reproducible nucleation of smooth, monocrystalline GaN layers on GaAs using a high-nitrogen-flow RF plasma source. In particular, thick single-phase GaN layers with smooth surface morphology are obtained being a prerequisite for the synthesis of ternary eta-(Ga,In,Al)N structures. Temperature dependent reflectance and transmittance measurements are carried out on such a GaN film having a RMS surface roughness as little as 1.5 nm. A numerical method is developed which allows to extract from these data the complete set of optical constants for photon energies covering the transparent as well as the strongly absorbing spectral range (2.0 -- 3.8 eV). Inhomogeneities in the refractive index leading to finite coherence effects are quantitatively analyzed by means of Monte Carlo simulations. The fundamental band gap EG(T) of GaN is determined for 5 < T < 300 K and the room temperature density of states is investigated. Systematic studies of the band edge photoluminescence (PL) in terms of transition energies, lineshapes, linewidths, and intensities are carried out for both alpha- and GaN as a function of temperature. Average phonon energies and coupling constants, activation energies for thermal broadening and quenching are determined. Excitation density dependent PL measurements are carried out for both phases in order to study the impact of nonradiative recombination processes at 300 K. A recombination model is applied to estimate the internal quantum efficiency, the (non)radiative lifetimes, as well as the ratio of the electron to hole capture coefficients for both polytypes. It is seen that the dominant nonradiative centers in the n-type material investigated act as hole traps which, however, can be saturated at already modest carrier injection rates. In summary, despite large defect densities in GaN due to highly mismatched heteroepitaxy on GaAs, band edge luminescence is observed up to 500 K with intensities comparable to those of state-of-the-art alpha-GaN. For the first time, thick InGaN films are fabricated on which blue and green luminescence can be observed up to 400 K for x=0.17 and x=0.4, respectively. Apart from bulk-like InGaN films, the first coherently strained InGaN/GaN (multi) quantum wells with In contents as high as 50 % and abrupt interfaces are grown. This achievement shows that a ternary alloy can be synthesized in a metastable crystal structure far beyond the miscibility limit of its binary constituents despite the handicap of highly lattice mismatched heteroepitaxy. The well widths of these structures range between 4 and 7 nm and are thus beyond the theoretically expected critical thickness for the strain values observed. It is to be expected that even higher In contents can be reached for film thicknesses below 5 nm. The potential application of such InGaN/GaN multi quantum wells with x >= 0.4 would thus be diode lasers operating in the green-yellow range. abstract in PostScript

Zinkblende GaN

Kubische Nitride

(In,Ga,Al)N Heterostrukturen

Multi Quantengräben

Verspannung

Molekularstrahlepitaxie

Reflektanz

Transmittanz

Optische Konstanten

Kohärenz

Photolumineszenz

Nichtstrahlende Rekombination

Quanten Effizienz

Ladungsträger Lebensdauer

Zincblende GaN

Cubic Nitrides

(In,Ga,Al)N Heterostructures

Multi Quantum Wells

Strain

Molecular Beam Epitaxy

Reflectance

Transmittance

Optical Constants

Coherence

Photoluminescene

Nonradiative Recombination

Quantum Efficiency

Carrier Lifetime

530 Physik

29 Physik, Astronomie

UP 3150

UP 7550

ddc:530