36 research outputs found
Towards smooth (010) beta-Ga2O3 films homoepitaxially grown by plasma assisted molecular beam epitaxy: The impact of substrate offcut and metal-to-oxygen flux ratio
Smooth interfaces and surfaces are beneficial for most (opto)electronic
devices based on thin films and their heterostructures. For example, smoother
interfaces in (010) beta-Ga2O3/(AlxGa1-x)2O3 heterostructures, whose roughness
is ruled by that of the Ga2O3 layer, can enable higher mobility 2DEGs by
reducing interface roughness scattering. To this end we experimentally prove
that a substrate offcut along the [001] direction allows to obtain smooth
beta-Ga2O3 layers in (010)-homoepitaxy under metal-rich conditions. Applying
In-mediated metal-exchange catalysis (MEXCAT) in molecular beam epitaxy at high
substrate temperatures (Tg = 900 {\deg}C) we compare the morphology of layers
grown on (010)-oriented substrates with different unintentional offcuts. The
layer roughness is generally ruled by (i) (110) and (-110)-facets visible as
elongated features along the [001] direction (rms < 0.5 nm), and (ii) trenches
(5-10 nm deep) orthogonal to [001]. We show that an unintentional substrate
offcut of only 0.1{\deg} almost oriented along the [001] direction suppresses
these trenches resulting in a smooth morphology with a roughness exclusively
determined by the facets, i.e., rms 0.2 nm. Since we found the facet-and-trench
morphology in layers grown by MBE with and without MEXCAT, we propose that the
general growth mechanism for (010)-homoepitaxy is ruled by island growth whose
coalescence results in the formation of the trenches. The presence of a
substrate offcut in the [001] direction can allow for step-flow growth or
island nucleation at the step edges, which prevents the formation of trenches.
Moreover, we give experimental evidence for a decreasing surface diffusion
length or increasing nucleation density with decreasing metal-to-oxygen flux
ratio. Based on our results we can rule-out step bunching as cause of the
trench formation as well as a surfactant-effect of indium during MEXCAT
Efficient suboxide sources in oxide molecular beam epitaxy using mixed metal + oxide charges: The examples of SnO and Ga2O
Sources of suboxides, providing several advantages over metal sources for the molecular beam epitaxy (MBE) of oxides, are conventionally realized by decomposing the corresponding oxide charge at extreme temperatures. By quadrupole mass spectrometry of the direct flux from an effusion cell, we compare this conventional approach to the reaction of a mixed oxide + metal charge as a source for suboxides with the examples of SnO2 + Sn â 2 SnO and Ga2O3 + 4 Ga â 3 Ga2O. The high decomposition temperatures of the pure oxide charge were found to produce a high parasitic oxygen background. In contrast, the mixed charges reacted at significantly lower temperatures, providing high suboxide fluxes without additional parasitic oxygen. For the SnO source, we found a significant fraction of Sn2O2 in the flux from the mixed charge that was basically absent in the flux from the pure oxide charge. We demonstrate the plasma-assisted MBE growth of SnO2 using the mixed Sn + SnO2 charge to require less activated oxygen and a significantly lower source temperature than the corresponding growth from a pure Sn charge. Thus, the sublimation of mixed metal + oxide charges provides an efficient suboxide source for the growth of oxides by MBE. Thermodynamic calculations predict this advantage for further oxides as well, e.g., SiO2, GeO2, Al2O3, In2O3, La2O3, and Pr2O3
Offcut-related step-flow and growth rate enhancement during (100) -Ga2O3 homoepitaxy by metal-exchange catalyzed molecular beam epitaxy (MEXCAT-MBE)
In this work we investigate the growth of -Ga2O3 homoepitaxial layers
on top of (100) oriented substrates via indium-assisted metal exchange
catalyzed molecular beam epitaxy (MEXCAT-MBE) which have exhibited
prohibitively low growth rates by non-catalyzed MBE in the past. We demonstrate
that the proper tuning of the MEXCAT growth parameters and the choice of a
proper substrate offcut allow for the deposition of thin films with high
structural quality via step-flow growth mechanism at relatively high growth
rates for -Ga2O3 homoepitaxy (i.e., around 1.5 nm/min, 45%
incorporation of the incoming Ga flux), making MBE growth on this orientation
feasible. Moreover, through the employment of the investigated four different
(100) substrate offcuts along the [00-1] direction (i.e., 0, 2,
4, 6) we give experimental evidence on the fundamental role of
the (-201) step edges as nucleation sites for growth of (100)-oriented Ga2O3
films by MBE
Enhancing Light Harvesting by Hierarchical Functionally Graded Transparent Conducting Al-doped ZnO Nano- and Mesoarchitectures
A functionally graded Al-doped ZnO structure is presented which combines
conductivity, visible transparency and light scattering with mechanical
flexibility. The nano and meso-architecture, constituted by a hierarchical,
large surface area, mesoporous tree-like structure evolving in a compact layer,
is synthesized at room temperature and is fully compatible with plastic
substrates. Light trapping capability is demonstrated by showing up to 100%
improvement of light absorption of a low bandgap polymer employed as the active
layer.Comment: 21 pages, 6 figures, submitted to Solar Energy Materials and Solar
Cell
Isotopic study of Raman active phonon modes in ÎČ-Ga2O3
Holding promising applications in power electronics, the ultra-wide band gap material gallium oxide has emerged as a vital alternative to materials like GaN and SiC. The detailed study of phonon modes in ÎČ-Ga2O3 provides insights into fundamental material properties such as crystal structure and orientation and can contribute to the identification of dopants and point defects. We investigate the Raman active phonon modes of ÎČ-Ga2O3 in two different oxygen isotope compositions (16O,18O) by experiment and theory: By carrying out polarized micro-Raman spectroscopy measurements on the (010) and (-201) planes, we determine the frequencies of all 15 Raman active phonons for both isotopologues. The measured frequencies are compared with the results of density functional perturbation theory (DFPT) calculations. In both cases, we observe a shift of Raman frequencies towards lower energies upon substitution of 16O with 18O. By quantifying the relative frequency shifts of the individual Raman modes, we identify the atomistic origin of all modes (Ga-Ga, Ga-O or O-O) and present the first experimental confirmation of the theoretically calculated energy contributions of O lattice sites to Raman modes. The DFPT results enable the identification of Raman modes that are dominated by the different, inequivalent O- or Ga-atoms of the unit cell. We find that oxygen substitution on the OII site leads to an elevated relative mode frequency shift compared to OI and OIII sites. This study presents a blueprint for the future identification of different point defects in Ga2O3 by Raman spectroscopy
Plasma-assisted molecular beam epitaxy of SnO(001) films: Metastability, hole transport properties, Seebeck coefficient, and effective hole mass
Transparent conducting or semiconducting oxides are important materials for
(transparent) optoelectronics and power electronics applications. While most of
these oxides can be doped n-type only with room-temperature electron mobilities
on the order of 100cm^2/Vs p-type oxides are needed for the realization of
pn-junction devices but typically suffer from exessively low (<<1cm^2/Vs) hole
mobilities. Tin monoxide (SnO) is one of the few p-type oxides with a higher
hole mobility, lacking a well-established understanding of its hole transport
properties. Moreover, growth of SnO is complicated by its metastability with
respect to SnO2 and Sn, requiring epitaxy for the realization of single
crystalline material typically required for high-end applications. Here, we
give a comprehensive account on the epitaxial growth of SnO, its
(meta)stability, and its thermoelectric transport properties in the context of
the present literature. Textured and single-crystalline, unintentionally-doped
p-type SnO(001) films are grown by plasma-assisted molecular beam epitaxy. The
metastability of this semiconducting oxide is addressed theoretically through
an equilibrium phase diagram. Experimentally, the related SnO growth window is
rapidly determined by an in-situ growth kinetics study as function of
Sn-to-O-plasma flux ratio and growth temperature. The presence of secondary Sn
and SnOx (1 < x <= 2) phases is comprehensively studied by different methods,
indicating the presence of Sn3O4 or Sn as major secondary phases, as well as a
fully oxidized SnO2 film surface. The hole transport properties, Seebeck
coefficient, and density-of-states effective mass are determined and critically
discussed in the context of the present literature on SnO, considering its
anisotropic hole-effective mass
Tuning electrical properties of hierarchically assembled Al-doped ZnO nanoforests by room temperature Pulsed Laser Deposition
Large surface area, 3D structured transparent electrodes with effective light management capability may represent a key component in the development of new generation optoelectronic and energy harvesting devices. We present an approach to obtain forest-like nanoporous/hierarchical Al-doped ZnO conducting layers with tunable transparency and light scattering properties, by means of room temperature Pulsed Laser Deposition in a mixed Ar:O2 atmosphere. The composition of the background atmosphere during deposition can be varied to modify stoichiometry-related defects, and therefore achieve control of electrical and optical properties, while the total background
pressure controls the material morphology at the nano- and mesoscale and thus the light scattering properties. This approach allows to tune electrical resistivity over a very wide range (10^-1 - 10^6 Ohm*cm), both in the in-plane and cross-plane directions. Optical transparency and haze can also be tuned by varying the stoichiometry and thickness of the nano-forests
Silane-Mediated Expansion of Domains in Si-Doped Îș-Ga2O3 Epitaxy and its Impact on the In-Plane Electronic Conduction
Unintentionally doped (001)-oriented orthorhombic Îș-Ga2O3 epitaxial films on c-plane sapphire substrates are characterized by the presence of â 10 nm wide columnar rotational domains that can severely inhibit in-plane electronic conduction. Comparing the in- and out-of-plane resistance on well-defined sample geometries, it is experimentally proved that the in-plane resistivity is at least ten times higher than the out-of-plane one. The introduction of silane during metal-organic vapor phase epitaxial growth not only allows for n-type Si extrinsic doping, but also results in the increase of more than one order of magnitude in the domain size (up to â 300 nm) and mobility (highest ” â 10 cm2Vâ1sâ1, with corresponding lowest Ï â 0.2 Ωcm). To qualitatively compare the mean domain dimension in Îș-Ga2O3 epitaxial films, non-destructive experimental procedures are provided based on X-ray diffraction and Raman spectroscopy. The results of this study pave the way to significantly improved in-plane conduction in Îș-Ga2O3 and its possible breakthrough in new generation electronics. The set of cross-linked experimental techniques and corresponding interpretation here proposed can apply to a wide range of material systems that suffer/benefit from domain-related functional properties