636 research outputs found
Dominant role of many-body effects on the carrier distribution function of quantum dot lasers
The effects of free-carrier-induced shift and broadening on the carrier distribution function are studied considering different extreme cases for carrier statistics (Fermi–Dirac and random carrier distributions) as well as quantum dot (QD) ensemble inhomogeneity and state separation using a Monte Carlo model. Using this model, we show that the dominant factor determining the carrier distribution function is the free carrier effects and not the choice of carrier statistics. By using empirical values of the free-carrier-induced shift and broadening, good agreement is obtained with experimental data of QD materials obtained under electrical injection for both extreme cases of carrier statistics
Epitaxial designs for maximizing efficiency in resonant tunnelling diode based terahertz emitters
We discuss the modelling of high current density InGaAs/AlAs/InP resonant tunneling diodes to maximize their efficiency as THz emitters. A figure of merit which contributes to the wall plug efficiency, the intrinsic resonator efficiency, is used for the development of epitaxial designs. With the contribution of key parameters identified, we analyze the limitations of accumulated stress to assess the manufacturability of such designs. Optimal epitaxial designs are revealed, utilizing thin barriers, with a wide and shallow quantum well that satisfies the strained layer epitaxy constraint. We then assess the advantages to epitaxial perfection and electrical characteristics provided by devices with a narrow InAs sub-well inside a lattice-matched InGaAs alloy. These new structures will assist in the realization of the next-generation submillimeter emitters
Modal Index Analysis of Resonances of PCSEL
This paper presents a new modal index analysis method for evaluating the resonances of PCSEL structures which is versatile, efficient and fast. Hence it is envisaged that the implementation of this method will enhance the potential to generate more comprehensive models of photonic crystal based devices, say, PCSELs, that include, for example, aspects of inversion population distribution and also time dependence while still retaining relatively modest demands on computational resources
Characterisation of High Current Density Resonant Tunneling Diodes for THz Emission Using Photoluminescence Spectroscopy
We discuss the numerical simulation of high current density InGaAs/AlAs/InP resonant tunneling diodes with a view to
their optimization for application as THz emitters. We introduce a figure of merit based upon the ratio of maximum
extractable THz power and the electrical power developed in the chip. The aim being to develop high efficiency emitters
as output power is presently limited by catastrophic failure. A description of the interplay of key parameters follows,
with constraints on strained layer epitaxy introduced. We propose an optimized structure utilizing thin barriers paired
with a comparatively wide quantum well that satisfies strained layer epitaxy constraints
Growth of quantum three-dimensional structure of InGaAs emitting at ~1 µm applicable for a broadband near-infrared light source
We obtained a high-intensity and broadband emission centered at ~1 µm from InGaAs quantum three-dimensional (3D) structures grown on a GaAs substrate using molecular beam epitaxy. An InGaAs thin layer grown on GaAs with a thickness close to the critical layer thickness is normally affected by strain as a result of the lattice mismatch and introduced misfit dislocations. However, under certain growth conditions for the In concentration and growth temperature, the growth mode of the InGaAs layer can be transformed from two-dimensional to 3D growth. We found the optimal conditions to obtain a broadband emission from 3D structures with a high intensity and controlled center wavelength at ~1 µm. This method offers an alternative approach for fabricating a broadband near-infrared light source for telecommunication and medical imaging systems such as for optical coherence tomography
Modelling and device simulation of photonic crystal surface emitting lasers based on modal index analysis
We present a novel semi-analytical method utilising modal index analysis, for modelling the field resonances of photonic crystal surface emitting lasers (PCSELs). This method shows very good agreement with other modelling techniques in terms of mode calculations, with the added advantages of computational simplicity, the calculation of threshold gain, and rapid analysis of finite structures. We are able to model the effect of external lateral feedback and simulations indicate that the near-field peak can be electronically displaced and the threshold as well as the frequency can be controlled through external in-plane feedback, paving the way to dynamic control of PCSELs
Gallium Nitride Super-Luminescent Light Emitting Diodes for Optical Coherence Tomography Applications
The role of biasing of absorber sections in multi-contact GaN ~400nm SLEDs is discussed. We go on to assess such devices for OCT applications. Analysis of the SLED emission spectrum allows an axial resolution of 6.0μm to be deduced in OCT applications
Coherently coupled photonic-crystal surface-emitting laser array
The realization of a 1 × 2 coherently coupled photonic crystal surface emitting laser array is reported. New routes to power scaling are discussed and the electronic control of coherence is demonstrated
Non-destructive characterization of thin layer resonant tunnelling diodes
We present an advanced nondestructive characterization scheme for high current density AlAs/InGaAs resonant tunneling diodes pseudomorphically grown on InP substrates. We show how low-temperature photoluminescence spectroscopy (LT-PL) and high-resolution X-ray diffractometry (HR-XRD) are complementary techniques to increase the confidence of the characterized structure. The lattice-matched InGaAs is characterized and found to be of high quality. We discuss the inclusion of an undoped “copy” well (C-well) in terms of enhancements to HR-XRD and LT-PL characterization and quantify the improved precision in determining the structure. As a consequence of this enhanced precision in the determination of physical structure, the AlAs barriers and quantum well (QW) system are found to contain nonideal material interfaces. Their roughness is characterized in terms of the full width to half-maximum of the split LT-PL emission peaks, revealing a ±1 atomic sheet variance to the QW width. We show how barrier asymmetry can be detected through fitting of both optical spectra and HR-XRD rocking curves
Fabrication, Characterisation, and Epitaxial Optimisation of MOVPE-Grown Resonant Tunnelling Diode THz Emitters
Resonant tunnelling diodes (RTDs) are a strong candidate for future wireless communications in the THz region,
offering compact, room-temperature operation with Gb/s transfer rates. We employ the InGaAs/AlAs/InP material
system, offering advantages due to high electron mobility, suitable band-offsets, and low resistance contacts. We
describe an RTD emitter operating at 353GHz, radiating in this atmospheric transmittance window through a slot
antenna. The fabrication scheme uses a dual-pass technique to achieve reproducible, very low resistivity, ohmic contacts,
followed by accurate control of the etched device area. The top contact connects the device via the means of an air
bridge. We then proceed to model ways to increase the resonator efficiency, in turn improving the radiative efficiency,
by changing the epitaxial design. The optimization takes into account the accumulated stress limitations and realities of
reactor growth. Due to the absence of useful in-situ monitoring in commercially-scalable metal-organic vapour phase
epitaxy (MOVPE), we have developed a robust non-destructive epitaxial characterisation scheme to verify the quality of
these mechanically shallow and atomically thin devices. A dummy copy of the active region element is grown to assist
with low temperature photoluminescence spectroscopy (LTPL) characterisation. The resulting linewidths limits the
number of possible solutions of quantum well (QW) width and depth pairs. In addition, the doping levels can be
estimated with a sufficient degree of accuracy by measuring the Moss-Burstein shift of the bulk material. This analysis
can then be combined with high resolution X-ray diffractometry (HRXRD) to increase its accuracy
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