MOVPE growth of grade-strained bulk InGaAs/InP for broad-band optoelectronic device applications

In this paper we present a novel growth of grade-strained bulk InGaAs/InP by linearly changing group-III TMGa source flow during low-pressure metalorganic vapor-phase epitaxy (LP-MOVPE).The high-resolution X-ray diffraction (HRXRD) measurements showed that much different strain was simultaneously introduced into the fabricated bulk InGaAs/InP by utilizing this novel growth method. We experimentally demonstrated the utility and simplicity of the growth method by fabricating common laser diodes. As a first step, under the injection current of 100 mA, a more flat gain curve which has a spectral full-width at half-maximum (FWHM) of about 120 nm was achieved by using the presented growth technique. Our experimental results show that the simple and new growth method is very suitable for fabricating broad-band semiconductor optoelectronic devices.     

MOVPE growth of InP/GaInAs and GaAs/GaInP heterostructures for electronic transport applications

The influence of the layer structure on the electrical properties in (i) modulation doped InP/GaInAs quantum well samples, and, (ii) GaAs/GaInP resonant tunneling diodes has been investigated. The results reveal the importance of the different scattering processes. In particular, the influence of interface roughness scattering has been evaluated for both types of structures.     

Highly uniform AlGaAs/GaAs and InGaAs(P)/InP structures grown in a multiwafer vertical rotating susceptor MOVPE reactor

Highly uniform AlGaAs/GaAs and InGaAs(P)/InP epitaxial layers have been grown in a vertical rotating susceptor MOVPE reactor capable of accommodating three 2′ wafers. The unique water-cooled “showerhead”-type injection distributor which is located 1.5 cm above the substrates ensures a uniform reactant distribution, resulting in uniform growth over a wide range of growth conditions. Periodic multilayer and single layer structures have been used to investigate the thickness and compositional uniformities. The thickness variations over a radial distance of 48 mm for three wafers grown in the same run are within ± 2% for both AlGaAs and InGaAs layers, resulting in a standard deviation of only 0.9%. The gallium concentration of an InGaAs layer varies from 46.88% to 47.01% over the same radial distance with the standard deviation of 0.043%. Measurements of InGaAsP layers grown onto 2′ InP wafers with different alloy compositions show good compositional uniformity yielding standard deviations within 4.4 nm in PL wavelength and 135 ppm in lattice mismatch over a 46 mm radial distance.     

Selectively embedded growth by chemical beam epitaxy for the fabrication of InGaAs/InP double-heterostructure lasers

In order to fabricate InGaAs/InP double-heterostructure (DH) lasers, a novel selectively embedded one-step growth by chemical beam epitaxy (CBE) was adopted. Before the selective CBE growth, 6–8 μm wide channels on an n-InP substrate were undercut by wet chemical etching through a 170 nm thick SiO₂ film mask. A 6 μm wide stripe-geometry DH laser structure with an active layer of 0.14 μm thickness was grown selectively with good planarity into the channels and operated by a pulse.     

Influence of growth parameters on the interface abruptness in CBE-grown InGaAs/InP QWs and SLs

A simple thermodynamic model for As and P incorporation at the CBE-grown InGaAs/InP and InP/InGaAs interfaces has been developed. This model agrees with the X-ray diffraction and the photoluminescence features experimentally obtained from high-quality single quantum wells (SQWs) and multi-quantum wells (MQWs). Our experimental results compare well with the best published data and clearly show that monolayer interfaces can be obtained in this material system only by chosing the proper growth interruption (GI) conditions and accepting a strong mismatch at each interface. This effect could become dramatic in superlattice structures in which the QW period is smaller than 5 nm and the resulting strain could lead to poor crystal quality and optical properties.     

VPE growth of InGaAS/InP structures using the hydride system

Some results on the VPE growth of InGaAs/InP structures in the hydride system using a single chamber horizontal reactor are described. The effect of partial pressures of the reactant gases and bypass-HCl on epitaxial growth of InGaAs is discussed. The GaCl partial pressure was found to be the deciding growth parameter.     

A modified zone growth method for an InGaAs single crystal

We have been developing a zone growth method for an In_xGa_1−xAs single crystal with a uniform InAs composition, using an InGaAs source, InGaAs melt and InGaAs seed charged in a crucible. This time, we modified the zone growth method to increase the length of an InGaAs zone crystal. A gap created between the wall around the InGaAs source and the inner wall of the crucible effectively prevents the interruption in normal zone growth because it changes the directions of heat current in the source. In addition, we found that it is very important for single crystal growth that no rotation of the crucible takes place during zone growth, because the degree of mixing caused by melt convection is reduced. The zone growth region of the obtained InGaAs crystal is almost exclusively of single-crystal-type, and it is about 26 mm long, which is 1.5 times the region length of the zone single crystal reported previously. We believe that a longer growth period could have further increased the length of our zone crystal, because some of the source remained. The InAs composition (x) of the zone crystal is greater than 0.3, and the crystal diameter is 15 mm.     

MOVPE growth of GaInP/GaAs hetero-bipolar-transistors using CBr4 as carbon dopant source

Carbon doping of GaAs with carbon tetrabromide (CBr₄) in low pressure MOVPE has been investigated and applied to the fabrication of GaInP/GaAs HBTs. Especially the hydrogen incorporation and the associated acceptor passivation has been studied. The hydrogen found in single GaAs:C layers is predominantly incorporated during cooling the sample under AsH₃ after growth, n-Type capping layers can block this H indiffusion and GaAs:C base layers in HBTs show much lower H concentrations than GaAs:C single layers without a cap. A further reduction of acceptor passivation is possible by optimization of the growth procedure. First HBTs processed from layers with a base that was doped using CBr₄ show promising DC and HF performance (β = 45, for 2 × 20 μm² devices).     

Molecular beam epitaxial growth and thermodynamic analysis of InGaAs and InAlAs lattice matched to InP

Reflection high-energy electron diffraction (RHEED) intensity oscillations have been used to detect the onset of metal droplet formation on the surface of InAs, InGaAs and InAlAs during molecular beam epitaxy. The growth conditions which produce such droplets are shown to be in good agreement with predictions based on thermodynamic arguments.     

Growth of InGaAs/GaAs on Offcut Substrates by MOVPE: Influence on Macrosteps and Dislocations Formation

A study of the relationship between the macrosteps caused by the substrate misorientation and dislocation nucleation in MOVPE-grown InGaAs/GaAs is presented. The macrosteps could favour strain relaxation and the decrease of the critical thickness, also by generation of misfit dislocations in the 1/2〈110〉{011} glide system, as they can provide sites for stress accumulation above the average value far from the macrosteps. This adds up to the enhanced homogeneous dislocation nucleation associated with the offcut angle. The use of offcut substrates thus produces both compositional inhomogeneities and an increase of the overall dislocation density.     

MOVPE growth of spontaneously ordered (GaIn) and (AlIn)P layers lattice matched to GaAs substrates

A systematic study of the metal-organic vapour-phase epitaxial growth of (GaIn)P and (AlIn)P layers deposited on GaAs substrates with (001) and (110) orientation is presented. Special attention has been paid to the growth on (001)-oriented wafers with different misorientations to the growth direction. The influence of the growth conditions on the properties of the epitaxial layers such as lattice mismatch, alloy composition, photoluminescence (PL) wavelength, FWHMs of PL peaks and atomic ordering is discussed. Layers with mirrorlike surfaces and various degrees of order could be deposited at growth temperatures T_g ranging from 595 °C to 750 °C for (GaIn)P and 720 °C to 800 °C for (AlIn)P. In addition to the influence of T_g on the Ga incorporation during the (GaIn)P growth we found the Ga distribution coefficient k_Ga to be affected by the misorientation of the substrates. k_Ga correlates presumably with the number of kinks and steps on the substrate surface. Transmission electron diffraction (TED) and PL investigations show that the degree of order — often described by the ordering paramter η — depends strongly on T_g the ordering is more pronounced when the layers are deposited on substrates misoriented towards the (1 11) lattice plane. Strong ordering has been observed for (GaIn)P samples grown at 680 °C on substrates 2° misoriented towards the [1 10] direction and at 650 °C on substrates 6° misoriented towards the same direction. For the (AlIn)P samples striking ordering has been found when they were grown at 720 °C.     

MOVPE growth and characterization of GaInAs(P) on (001) InP using diethyltertiarybutylarsine (DEtBAs) and tertiarybutylphosphine (TBP) as the group-V sources

We report on low pressure MOVPE results of (GaIn)As grown with the arsenic precursor DEtBAs as well as (GaIn)(AsP) grown on InP using the precursor combinations DEtBAs/TBP, DEtBAs/PH₃ which we carefully compared with samples grown in the standard system (AsH₃/PH₃). Lattice matched (GaIn)As layers have been obtained at a growth temperature of 600°C, a V/III ratio of 3 and at a growth rate of 1 μm/h at a reactor pressure of 50 mbar. Changing the As precursor from AsH₃ to DEtBAs simultaneously alters the incorporation coefficient ratio k_Ga/k_In from 1.15 to 1. At room temperature n-type mobilities of 9060 cm²/V s have been achieved for (GaIn)As grown with DEtBAs at a V/III ratio of 2. Besides the excitonic luminescence at 802 meV a lower energy peak appears in the photoluminescence (PL) spectra at 753 meV (carbon-carbon donor-acceptor pair). The excitonic luminescence peak has a FWHM of about 9 meV. The (GaIn)(AsP) layers have been grown at a growth temperature of 625°C and V/III ratios of 15–25 with DEtBAs/TBP and about 60 with DEtBAs/PH₃. Layers grown with higher V/III ratios show an enhanced As content. However, considering the P incorporation we have observed a qualitative difference between the standard hydride system and systems using alternative group-V precursors. Even in the system DEtBAs/PH₃ the phosphorus incorporation is much higher than in the AsH₃/PH₃ system indicating the influence of vapor phase exchange reactions.     

CBE growth of InGaAsP/InP multiple quantum wells for optical modulator applications

The incorporation of group III and group V in the chemical beam epitaxy of InGaAsP/InP multiple quantum well structures has been studied in the temperature range of 470 to 550°C. Both Ga/In and P/As composition ratios are found to be strongly dependent on the growth temperature. The enhancement of phosphorus incorporation at high temperature is identified for the first time, which has a profound impact on the incorporation of group III, in particular the adsorption/pyrolysis of triethygallium. With accurate growth temperature control, high quality InGaAsP/InP superlattices with a large number of periods can be grown under continuous growth mode. Clear quantum confined Stark effect near 1.5 μm has been observed in a p-i-n test modulator structure.     

InGaAs/InAlAs in-plane superlattices grown on slightly misoriented (110) InP substrates by molecular beam epitaxy

InGaAs/InAlAs in-plane superlattices (IPSLs) composed of InAs/GaAs and InAs/AlAs monolayer superlattices were grown using molecular beam epitaxy. The substrates were misoriented (110) InP tilting 3° toward the [00 ] direction. We grew half monolayers of AlAs and GaAs and single monolayers of InAs alternately, keeping regular arrays of single monolayer steps. The structures were evaluated by transmission electron microscopy (TEM). In a transmission electron diffraction pattern from the ( 10) cross-section, we observed two types of superstructure spot pairs double-positioned in the [001] direction, indicating the formation of the intended IPSL structures. In a cross-sectional TEM dark-field image, we observed the InGaAs/InAlAs superlattice structures formed almost in the [001] direction. The mean period of the superlattices was approximately 4 nm, which was comparable to the terrace width expected from the substrate tilt angle. However, IPSL structures were not completely formed, i.e., the lateral interfaces meandered along the growth direction, and partial disorderings were often observed. The photoluminescence spectrum from the IPSL had a peak corresponding to the InGaAs (2 nm thick)/InAlAs (2 nm thick) superlattice in addition to a peak corresponding to the In_0.5Al_0.25Ga_0.25As alloy.     

Alternative precursors for MOVPE growth of InN and GaN at low temperature

We report on the use of dimethylhydrazine (DMHy) and tertiarybuthylhydrazine (TBHy), as alternative nitrogen precursor for GaN low-temperature growth, as well as to improve the InN growth rate. Lowering the GaN growth temperature, would allow growing InN/GaN heterostructures by MOVPE, without damaging the InN layers. Increasing the low InN MOVPE growth rate is of major importance to grow reasonably thick InN layers. In this respect, triethylindium (TEIn) was also used as an alternative to trimethylindium (TMIn).     

Properties of (Ga0.47In0.53)As epitaxial layers grown by metalorganic vapor phase epitaxy (MOVPE) using alternative arsenic precursors

In this study, the use of novel, liquid, organic arsenic precursors as substitutes for the highly toxic hydride gas arsine (AsH₃) in low pressure metalorganic vapor phase epitaxy (LP-MOVPE) of (GaIn)As lattice matched on InP has been investigated. The model precursors out of the classes of (alkyl)3-nAsH_n (n = 0,1,2) are tertiarybutyl arsine (TBAs), ditertiarybutyl arsine (DitBAsH) and diethyltertiarybutyl arsine (DEtBAs). The MOVPE growth has been investigated in the temperature range of 570–650°C using V/III ratios from 2 to 20. The obtained epitaxial layer quality as examined by means of optical and scanning electron microscopy (SEM), high resolution double crystal X-ray diffraction, temperature-dependent van der Pauw-Hall, as well as photoluminescence (PL) measurements, will be compared for the different source molecules. Under optimized conditions almost uncompensated n-type (GaIn)As layers with carrier concentrations below 1 × 10¹⁵ cm⁻³ and corresponding mobilities above 80 000 cm²/V · s have been realized. For TBAs and DitBAsH in combination with the corresponding P sources TBP and DitBuPH, respectively, we have worked out a process parameter area for the growth of layers with device quality, as proven by the realization of a pin-detector structure.     

Reflectance anisotropy as an in situ monitor for the growth of InP on (001) InP by pseudo-atmospheric pressure atomic layer epitaxy

Single wavelength reflectance anisotropy (RA) has been used to monitor the growth of InP onto (001) InP substrates in real time under atmospheric pressure atomic layer epitaxy “(ALE)-like” conditions in which the In and P precursors were introduced sequentially into the reactor. The RA data indicates that at temperatures below 325°C the initial interaction of TMI with surface P-dimers results in a change in anisotropy and that the resulting surface is unreactive towards phosphine or additional TMI possibly as a result of a residual species of the type In(CH₃)_x where x = 1–3 acting as a site blocker or preventing In dimer formation. At higher temperatures, the RA data indicates that for InP growth on (001) InP using phosphine and trimethylindium (TMI) the onset of growth occurs between 300–325°C. This observation is implied directly from the appearance of the recovery portion of the RA transient which indicates that the second half of the ALE-like cycle restores the surface to the starting P-stabilised conditions. This low temperature for the onset of growth as compared to conventional InP MOCVD is attributed to the operation of a surface catalysed reaction of both phosphine and TMI.     

Thermodynamic analysis of the MOVPE growth of InxGa1−xN

A chemical equilibrium model is applied to the growth of the In_xGa_1−xN alloy grown by metalorganic vapor-phase epitaxy (MOVPE). The equilibrium partial pressures and the phase diagram of deposition are calculated for the In_xGa_1−xN alloy. The vapor-solid distribution relationship is discussed in comparison with the experimental data reported in the literature. It is shown that the solid composition of the In_xGa_1−xN alloy grown by MOVPE is thermodynamically controlled and that the incorporation of group III elements into the solid phase deviates from a linear function of the input mole ratio of the group III metalorganic sources under the conditions of high mole fraction of decomposed NH₃ (high value of ), high temperature and low input V/III ratio. The origin of the deviation of the solid composition from the linear relation is also discussed.     

MOVPE growth and properties of GaN on (1 1 1)Si using an AlInN intermediate layer

Using an AlInN intermediate layer, GaN was grown on (1 1 1)Si substrate by selective metalorganic vapor phase epitaxy. The variation of the surface morphology was investigated as a function of the In composition and thickness of the AlInN layer. It was found that the In composition in the AlInN layer was a function of the growth temperature and thickness. Because of the small band offset at the AlInN/Si hetero-interface, we have achieved a low series resistance of the order of 9 Ω (0.0036 Ω cm²) across the GaN/AlInN/AlN/Si layer structure.