Growth mechanism and defects analyses of ZnO epitaxial layer on £^- LiAlO2(200) substrate

Huang, Teng-hsing

17 July 2008

"none"

threading dislocation

CVD

ZnO

LiAlO2

CAFM Studies of Epitaxial Lateral Overgrowth GaN Films

Kasliwal, Vishal P.

01 January 2007

This thesis uses the techniques of atomic force microscopy (AFM) and conductiveAFM (CAFM) to study defect sites on GaN films. In particular, these defect sites demonstrate current leakage under reverse-bias conditions that are detrimental to device fabrication. Two growth techniques that were used to improve this leakage behavior for samples in this study included: epitaxial lateral overgrowth (ELO) and nano-ELO using a Si3N4 film. Both techniques decrease defects such as threading dislocations by controlling the nucleation and growth behavior of the GaN films. The EL0 technique uses a patterned dielectric film to laterally grow micron-wide regions (referred to as 'wings') that minimize dislocation defects. Our CAFM studies indicate that ELO films have no detectable leakage sites in these wing regions; however, between these regions the films have typical leakage site densities seen for standard films on the order of 107cm-3. The nano-ELO technique utilizes a porous Si3N4 film to reduce defects over the entire film, and CAFM data indicate nearly a factor of ten reduction in leakage site densities. The nano-ELO technique is therefore optimal for an overall improvement in film quality, whereas the ELO technique is suitable for device fabrication in patterned regions with optimized film quality.

threading dislocation

semiconductor

growth behavior

leakage

defect site

gallium nitride

Physical Sciences and Mathematics

Physics

Quantum well state of cubic inclusions in hexagonal silicon carbide studied with ballistic electron emission microscopy

Ding, Yi

17 June 2004

No description available.

Physics, Condensed Matter

SiC

GaN

polytypism

inclusion

stacking fault

quantum well

ballistic electron emission microscopy

Schottky barrier

threading dislocation

Investigation and Characterization of AlGaN/GaN Device Structures and the Effects of Material Defects and Processing on Device Performance

Jessen, Gregg Huascar

20 December 2002

No description available.

III-Nitride

AlGaN/GaN

AlGaN

GaN

heterostructure

heterojunction

interfaces

defects

threading dislocation

devices

HEMT

HFET

HBT

memory effect

transistor

fabrication

characterization

CLS

Cathodoluminescence

LEEN

yellow luminescence

III-V semiconductors on SiGe substrates for multi-junction photovoltaics

Andre, Carrie L.

19 November 2004

No description available.

Physics, Condensed Matter

Si

SiGe

GaAs

InGaP

GaInP

solar cells

photovoltaics

dual junction

heteroepitaxy

lattice-mismatch

threading dislocation

minority carrier lifetime

reverse saturation current

open-circuit voltage

Transmission electron microscopy studies of GaN/gamma-LiAlO 2 heterostructures

Liu, Tian-Yu

15 June 2005

Die vorliegende Arbeit beschaeftigt sich mit dem strukturellen Aufbau von (1-100) M-plane GaN, das mit plasmaunterstuetzter Molekularstrahlepitaxie auf gamma-LiAlO2(100) Substraten gewachsen wurde. Die heteroepitaktische Ausrichtung einerseits, sowie die Mikrostruktur und die Erzeugungsmechanismen der Defekte andererseits, wurde mit der Transmissionselektronenemikroskopie (TEM) systematisch untersucht. Das gamma-LiAlO2 Substrat reagiert heftig im Mikroskop unter Bestrahlung mit hochenergetischen Elektronen. Waehrend dieser Strahlenschaedigung verliert das Material seine urspruengliche kristalline Struktur und vollzieht eine Phasentransformation, die anhand einer Serie von Feinbereichsbeugungsdiagrammen nachgewiesen werden konnte. Die atomare Grenzflaechenstruktur zwischen epitaktisch gewachsenem alpha-GaN(1-100) und tetragonalem gamma-LiAlO2 Substrat ist mittels HRTEM untersucht worden. Die neuartige Epitaxiebeziehung ist mit Elektronenbeugung bestaetigt worden und lautet folgendermassen: (1-100)GaN liegt parallel zu (100)gamma-LiAlO2 und [11-20]GaN ist parallel zu [001]gamma-LiAlO2. Die Realstruktur der M-plane GaN Schichten, die auf (100)gamma-LiAlO2 gewachsen werden, unterscheidet sich erheblich von der in C-plane Orientierung hergestellten Epischichten. Ausfuehrliche TEM Untersuchungen zeigen, dass die M-plane Schichten vor allem intrinsische (I1 und I2) und extrinsische (E) Stapelfehler in der Basalebene enthalten. Der vorherrschende I2 Stapelfehler besitzt keine Komponente des Verschiebungsvektors senkrecht zur Ebene und ist damit nicht geeignet, epitaktische Dehnung entlang der [11-20] Richtung abzubauen. Darueberhinaus ist eine komplexe Grenze in der (10-10) Prismen- flaeche entdeckt worden, die zur Grenzflaeche geneigt verlaeuft. Die Defekte in den M-plane GaN Epischichten werden waehrend der anfaenglichen Keimbildungsphase erzeugt. Atomare Stufen entlang der [001] Richtung auf dem LiAlO2 Substrat fuehren zur Bildung von Stapelfehlern vom Typ I2. / In this work the structure of (1-100)M-plane GaN epitaxially grown on gamma-LiAlO2(100) by using plasmaassisted molecular beam epitaxy (PAMBE) is studied. The heteroepitaxial alignment and the microstructure of M-plane GaN as well as the defect formation in the layer are systematically investigated by using transmission electron microscopy (TEM). The gamma-LiALO2 substrate reacts under irradiation of high-energy electrons in the TEM (200-300 keV).The material looses its original crystalline structure during this process undergoing irradiation damage followed by a phase transformation as it is verified by a series of selected area diffraction patterns taken under constant electron dose. The result is a structural phase transformation from the tetragonal gamma to the trigonal alpha phase. The atomic interface structure of epitaxially grown hexagonal alpha-GaN(1-100) layers on tetragonal gamma-LiAlO2 (100) substrates is investigated by means of HRTEM. The novel epitaxial orientation relationship verified by electron diffraction is given by (1-100)GaN parallel to (100)gamma-LiAlO2 and [11-20]GaN parallel to [001]gamma-LiAlO2. The defect structure of M-plane GaN epilayers grown on gamma-LiAlO2(100) substrates is different to that of C-plane GaN. Our detailed TEM studies reveal that the M-plane layers mainly contain intrinsic I1 and I2 and extrinsic E basal plane stacking faults. The dominant I2 stacking fault has no out-of-plane displacement vector component and is thus not qualified for epitaxial strain relief along the [11-20] axis. Beyond this, a complex type of planar defect is detected in the (10-10) prism plane which is inclined with respect to the interface. The study of nucleation samples shows that the surface morphology is directly correlated to the generation of the dominant planar defects. Atomic steps along the [001] direction in the gamma-LiAlO2 substrate result in the formation of basal plane stacking faults I2.

Epitaxie von Galliumnitrid

GaN

Epitaxie

Transmissionselektronenmikroskop

Transmissionselektronenmikroskopie

Schraubenversetzung

Stapelfehler

Domaenengrenze

Nukleation

Burgers-Vektor

Verzerrung durch Gitterfehlanpassung

Verschiebungsvektor

gallium nitride epitaxy

GaN

epitaxy

transmission electron microscope

transmission electron microscopy

threading dislocation

stacking fault

domain boundary

nucleation

Burgers vector

misfit strain

displacement vector

530 Physik

29 Physik, Astronomie

ddc:530