Influence of the cap layer thickness on photoluminescence properties in strained InGaAs/GaAs single quantum wells

The influence of the GaAs cap layer thickness on the luminescence properties in strained In_0.20Ga_0.80As/GaAs single quantum well (SQW) structures has been investigated using temperature-dependent photoluminescence (PL) spectroscopy. The luminescence peak is shifted to lower energy as the GaAs cap layer thickness decreases, which demonstrates the effect of the GaAs cap layer thickness on the strain of InGaAs/GaAs single quantum wells (SQW). We find the PL quenching mechanism is the thermal activation of electron hole pairs from the wells into the GaAs cap layer for the samples with thicker GaAs cap layer, while in sample with thinner GaAs cap layer exciton trapping on misfit dislocations is dominated.     

Time-resolved spectra and kinetics of the exciton photoluminescence in different types of GaAs/AlAs superlattices

The temperature dependence of the recombination dynamics of excitons is investigated by time-resolved photoluminescence spectroscopy in(GaAs)_n / (AlAs)_n superlattices, where n denotes the layer thickness in monolayers, for different types of band structures. In direct-gap superlattices with a layer thickness of the order or larger than the exciton Bohr radius, the carrier dynamics is dominated by the transfer from light-hole to heavy-hole excitons. When the layer thickness becomes smaller than the exciton radius, the dynamics of free excitons is controlled by localization. vb In quasi-direct and indirect-gap superlattices, the influence of lateral potential fluctuations due to interface roughness completely governs exciton recombination.     

Exciton line broadening in strained InGaAs/GaAs single quantum wells

We report the first observation of well-resolved exciton peaks in the room-temperature absorption spectrum of the strained In_0.20Ga_0.80As/GaAs Single Quantum-Well (SQW) structure. The best fit of the exciton resonances gives the conduction-band offset ratioQ _c=0.70±0.05. The strength of the exciton-phonon coupling is determined from linewidth analysis and is found to be much larger than that of strained InGaAs/GaAs MQW structures.     

Investigation of various optical transitions in GaAs/Al0.3Ga0.7As double quantum ring grown by droplet epitaxy

This work examines the optical transitions of a GaAs double quantum ring (DQR) embedded in Al_0.3Ga_0.7As matrix by photoreflectance spectroscopy (PR). The GaAs DQR was grown by droplet epitaxy (DE). The optical properties of the DQR were investigated by excitation‐intensity and temperature‐dependent PR. The various optical transitions were observed in PR spectra, whereas the photoluminescence (PL) spectrum shows only the DQR and GaAs band emissions. The various optical transitions were identified for the GaAs near‐band‐edge transition, surface confined state (SCS), DQR confined state, wetting layer (WL), spin–orbital split (E_GaAs + Δ_o), and AlGaAs band transition. PR spectroscopy can identify various optical transitions that are invisible in PL. The PR results show that the GaAs/AlGaAs DQR has complex electronic structures due to the various interfaces resulting from DE.     

Ground state energy of the electron-hole liquid in type-II (GaAs)m/(AlAs)m quantum wells

The ground state energy of quasi-two-dimensional electron-hole liquid (EHL) at zero temperature is calculated for type-II (GaAs)_m/(AlAs)_m (5≤m≤10) quantum wells (QWs). The correlation effects of Coulomb interaction are taken into account by a random phase approximation of Hubbard. Our EHL ground state energy per electron-hole pair is lower than the exciton energy calculated recently for superlattices, so we expected that EHL is more stable state than excitons at high excitation density. It is also demonstrated that the equilibrium density of EHL in type-II GaAs/AlAs QWs is of one order of magnitude larger than that in type-I GaAs/AlAs QWs.     

Magneto-photoluminescence study of type-II charge confinement in epitaxially grown GaInP2

We have studied the photoluminescence from GaInP₂ grown by molecular beam epitaxy as a function of laser power, magnetic field and temperature. We show that the single luminescence peak observed in such samples arises from weakly bound (type-II) excitons in which the electrons are localised and the holes are free, and that it is the same as the additional low-energy peak typically observed in strongly CuPt-ordered GaInP₂ grown by chemical vapour deposition techniques. We propose that the electron is confined in In-rich regions of the sample and the hole is delocalised by coupling between heavy- and light-hole bands.     

Electro-absorption modulator using a type-II quantum well in the InxGa1 − xAs/InAlAs/InP system

In this paper photoluminescence measurements at low temperature under different excitation powers were carried out on an InGaAs tensile strained (x =  0.3) quantum well with InGaAs barriers lattice matched (LM) to InP. Evidence of a type-II recombination was found between carriers confined in the tensile layer and in the LM layer. This study allows us to deduce an accurate determination of the conduction band offset in the In_0.3Ga_0.7As/In_0.53Ga_0.47As/InP system. Moreover, we include the previous type-II structure between InAlAs barriers in order to confine both electrons and holes. This structure has potential applications in electro-optical modulators. We simulate its optical modulation by solving the Schrödinger equation using the envelope function approximation and calculating the absorption spectrum taking into account excitonic effects.     

Investigation of band non-parabolicities in strain-balanced GaInAs/GaAlInAs coupled quantum wells

Magneto-optical investigations of a series of strain-balanced InGaAs/GaAlInAs coupled quantum wells are described, showing how changes in the strain within the InGaAs wells modify the conduction and valence-band dispersion curves. Large non-parabolicities in both bands are demonstrated by comparison of measured and calculated excitonic Landau levels. Increasing tensile strain within the wells results in the heavy-hole in-plane mass changing from a very high value to less than 0.2m₀as the first light-hole confined level shifts to an energy above that of the first heavy-hole state.     

Magneto-optic determination of the light-hole effective masses in InGaAs/GaAs strained-layer superlattices

Low-temperature magneto-luminescence studies on strained layer superlattices are used to determine in-plane light-hole band effective masses in both n- and p-type InGaAs/GaAs structures.     

MBE GaAs1-xSbx/GaAs应变层量子阱的光调制反射光谱

本文采用光调制反射光谱技术研究了MBE GaAs_1-xSb_x/GaAs应变层量子阱。通过实验分析和理论上对受应力作用后能带结构的估算,确认在这一系统中流体静压力作用引起的能带结构变化主要出现在导带上,同时也证实了GaAs_1-xSb_x/GaAs应变层量子阱属于第Ⅱ型量子阱结构。实验结果与理论估算符合很好。 关键词：     

Annealing effect on the optical properties in Si delta-doped Al0.24Ga0.76As/In0.15Ga0.85As/GaAs pseudomorphic high electron mobility transistor structures

The optical properties of Si delta-doped Al_0.24Ga_0.76As/In_0.15Ga_0.85As/GaAs pseudomorphic high electron mobility transistor structure (PHEMTs) are estimated after the process of rapid thermal annealing (RTA) in the temperature range 500–750°C. After layer intermixing and decrease of 2DEG densities of PHEMTs just occurs around the annealing temperature of 650°C, the 12H transition peak at 1.354 eV above the annealing temperature of 650°C is newly observed from the photoluminescence (PL) and photoreflectance (PR) spectra. From the results of PL and PR measurements in the annealed PHEMTs, it is found that remarkable modification of band profile in InGaAs QW occur at annealing temperature above 650°C.     

Stabilization energies of charged multiexciton complexes calculated at configuration interaction level

Recombination and stabilization energies of multiexcitons confined in positively and negatively charged semiconductor InGaAs/GaAs quantum dot (QD) samples have been studied by employing large-scale configuration interaction (CI) calculations. The CI calculations show that at most six electrons or two holes can be confined in the QD. Multiply charged multiexciton complexes with up to five excess electrons or two excess holes are also found to be stable, even when a few electron–hole pairs are present in the QD. The chemical potential functions for charged QD samples do not possess the pronounced stepped form as obtained for the corresponding neutral multiexciton complexes. The negatively and the positively charged excitons (negative and positive trions) lie lower in energy as compared to a neutral exciton and a single non-interacting charge carrier in the lowest single-particle state of another quantum dot. The other charged multiexciton complexes studied are not confined with respect to the corresponding neutral multiexciton and a non-interacting charge carrier. To include the contributions from the heavy-hole light-hole (HH–LH) coupling, a perturbative treatment of the band-mixing effects was implemented. The perturbation-theory calculations show that the HH–LH coupling does not shift the energies in the present InGaAs/GaAs QD sample.     

Exciton/plasmon mixing in metal–semiconductor heterostructures

We report on the strong coupling between surface plasmons and inorganic quantum well excitons. The sample is formed by a corrugated silver film deposited on the top of a heterostructure consisting of five GaAs/GaAlAs quantum wells grown by molecular beam epitaxy. Reflectometry experiments at low temperature (77 K) evidence the formation of plasmon/heavy-hole exciton/light-hole exciton mixed states. The interaction energies, deduced by fitting the experimental data with a coupled oscillator model, amount to 22 meV for the plasmon/light-hole exciton and 21 meV for the plasmon/heavy-hole exciton. Some particularities of the plasmon–exciton coupling are also discussed and qualitatively related to the plasmon polarization.     

Intermixing behavior in InGaAs/InGaAsP multiple quantum wells with dielectric and InGaAs capping layers

The influence of the InGaAs capping layer on the intermixing behavior of dielectric-capped In_0.53Ga_0.47 As/In_0.81Ga_0.19As_0.37P_0.63 multiple quantum wells (MQWs) was investigated by measuring the change in the photoluminescence spectra after rapid thermal annealing. The magnitude of the energy shift in the transition energy from the first electronic sub-band to the first heavy- and light-hole sub-bands of the MQWs is large when SiO₂ and InGaAs hybrid capping layers are employed, but it is rather small when Si₃N₄ and InGaAs hybrid capping layers are employed. This result indicates that the InGaAs capping layer holds promise for applications involved in the fabrication of integrated photonic devices, but only when it is incorporated with the SiO₂ capping layer. The reason why the InGaAs capping layer behaves differently under the SiO₂ and Si₃N₄ capping layers is also discussed. Received: 4 December 1999 / Accepted: 26 September 2000 / Published online: 10 January 2001     

Strain-confined wires and dots at a GaAs/AlxGa1-xAs interface

We have observed lateral exciton confinement at the GaAs/Al_xGa_1-xAs interface. The confinement is achieved in both the growth and lateral directions by the strain potential under an amorphous carbon stressor. The potential welt varies from 15 meV to 40 meV for different stressor sizes. We have also made transient measurements on this structure, which show efficient exciton transfer from the bulk GaAs to the confined region.     

Spacer layer thickness fluctuation scattering in a modulation-doped AlxGa1-xAs/GaAs/AlxGa1-xAs quantum well

We theoretically study the influence of spacer layer thickness fluctuation（SLTF） on the mobility of a twodimensional electron gas（2DEG） in the modulation-doped Al x Ga 1 x As/GaAs/Al x Ga 1 x As quantum well.The dependence of the mobility limited by SLTF scattering on spacer layer thickness and donor density are obtained.The results show that SLTF scattering is an important scattering mechanism for the quantum well structure with a thick well layer.     

Excitons in quantum—dot quantum—well nanoparticles

A variational calculation is presented for the ground-state properties of excitons confined in spherical core-shell quantum-dot quantum-well (QDQW) nanoparticles. The relationship between the exciton states and structure parameters of QDQW nanoparticles is investigated, in which both the heavy-hole and the light-hole exciton states are considered. The results show that the confinement energies of the electron and hole states and the exciton binding energies depend sensitively on the well width and core radius of the QDQW structure. A detailed comparison between the heavy-hole and light-hole exciton states is given. Excellent agreement is found between experimental results and our calculated 1s_e－1s_h transition energies.     

Photoreflectance and photoluminescence study of short period (GaAs)n/(AlAs)n superlattices with n = 1 – 15

Photoreflectance and photoluminescence measurements were performed in (GaAs)_n/(AlAs)_n (n = 1 – 15) short-period superlattices in the temperature range from 25 K to 275 K. Weak signals of photoreflectance associated with the critical point of the pseudodirect transition, weakly allowed direct transition arising from the zone-folding effect, have been observed as well as main signals associated with the direct allowed transitions. This assignment is supported by the measurement and analysis of the temperature dependence of the photoluminescence intensity.     

Low temperature photoluminescence of GaxIn1−xAs/GaAs strained layer superlattices

The low temperature photoluminescence spectra of several Ga_xIn_1−xAs/GaAs strained layer superlattices have been measured. Excitomic recombination between electrons and holes confined in the ternary layers and conduction band-acceptor transitions have been observed. The excitonic transition energies calculated with a simple model which takes into account both strain and quantization are in good agreement with the measured values provided the additional strain due to the mismatch between the SLS and the buffer layer is taken into account. The hydrogenic acceptor binding energy is smaller in the SLS than in the bulk ternary because the reduction due to the decrease of the hole mass under strain appears to be more important than the two dimensional quantization enhancement in the present samples.     

High-k Al2O3 MOS structures with Si interface control layer formed on air-exposed GaAs and InGaAs wafers

This paper attempts to realize unpinned high-k insulator-semiconductor interfaces on air-exposed GaAs and In_0.53Ga_0.47As by using the Si interface control layer (Si ICL). Al₂O₃ was deposited by ex situ atomic layer deposition (ALD) as the high-k insulator. By applying an optimal chemical treatment using HF acid combined with subsequent thermal cleaning below 500 °C in UHV, interface bonding configurations similar to those by in situ UHV process were achieved both for GaAs and InGaAs after MBE growth of the Si ICL with no trace of residual native oxide components. As compared with the MIS structures without Si ICL, insertion of Si ICL improved the electrical interface quality, a great deal both for GaAs and InGaAs, reducing frequency dispersion of capacitance, hysteresis effects and interface state density (D_it). A minimum value of D_it of 2 × 10¹¹ eV⁻¹ cm⁻² was achieved both for GaAs and InGaAs. However, the range of bias-induced surface potential excursion within the band gap was different, making formation of electron layer by surface inversion possible in InGaAs, but not possible in GaAs. The difference was explained by the disorder induced gap state (DIGS) model.