Surface Architectures on Gallium Nitride Light Emitting Diodes for Light Extraction Improvement

Lin, Jia-chi

02 August 2010

In recent years, even though the light output of GaN-related LED continues to increase, the brightness is still low compared to conventional lighting systems and it is necessary to further improve the light extraction of LEDs. In this study, we utilize the ZnO nanotip with aqueous solution and flip-chip technique to increase the light extraction of GaN LEDs. Electroluminescence (EL) and angular optical distribution are used to measure the light output intensity of LED. In the results, ZnO nanotip after thermal annealing with N2O ambiance decrease the ZnO defects. Flip-chip LED has higher light intensity ( 1.25 times) than conventional one in vertical emitting area ( at 0 angles). The enhancement of light output is duo to the reduction of light absorption from the metal contact and Fresnel¡¦s transmission losses. Finally, we fabricate a high brightness LED with above light enhancement design. EL intensity of LED is increased about 1.38 times than conventional one. Therefore, we can manufacture a LEDs array with above designs to obtain high light output for future solid-state illumination.

GaN LED

ZnO nanotip

light extraction efficiency

Micro Structures on Gallium Nitride Light Emitting Diodes for Light Extraction Improvement

Ho, Chen-Lin

15 July 2008

In recent years, even though the light output of GaN-related LED continues to increase, the brightness is still low compared to conventional lighting systems and it is necessary to further improve the light extraction of LEDs. In this study, the characteristics of LPD-SiO2 film and Al/SiO2/GaN MOS diode were investigated in advance of the formation of SiO2 micro structure for improving the oxide quality and controlling the deposition parameters. Temperature-difference method, post-annealing treatment, photochemical treatment, sulfurated treatment and etc. were used for the purposes of better properties of the MOS structure and the LED. To obtain higher light extraction efficiency of GaN LED, hemispherical SiO2 microlens was formed on the conventional and the flip-chip LEDs. The deposition mechanism had been developed to obtain the further improvements on the electrical and optical properties. The influences of epoxy encapsulation on the LEDs without and with microlens were also studied. Considering the refractive index of SiO2 is close to that of the epoxy, the enhancements of light extraction efficiency and angular optical distribution of GaN LED by using SiO2 microlens will be degraded after encapsulating. Therefore, we also tried to deposit ZnO film and rod on GaN LED by LPD method to maintain or further enhance the light extraction efficiency of GaN LEDs by the combining the micro structure and the epoxy encapsulation.

light extraction efficiency

microlens

ZnO

GaN LED

SiO2

Light Management in Optoelectronic Devices with Disordered and Chaotic Structures

Khan, Yasser

07 1900

With experimental realization, energy harvesting capabilities of chaotic microstructures were explored. Incident photons falling into chaotic trajectories resulted in energy buildup for certain frequencies. As a consequence, many fold enhancement in light trapping was observed. These ellipsoid like chaotic microstructures demonstrated 25% enhancement in light trapping at 450nm excitation and 15% enhancement at 550nm excitation. Optimization of these structures can drive novel chaos-assisted energy harvesting systems. In subsequent sections of the thesis, prospect of broadband light extraction from white light emitting diodes were investigated, which is an unchallenged but quintessential problem in solid-state lighting. Size dependent scattering allows microstructures to interact strongly with narrow-band light. If disorder is introduced in spread and sizes of microstructures, broadband light extraction is possible. A novel scheme with Voronoi tessellation to quantify disorder in physical systems was also introduced, and a link between voronoi disorder and state disorder of statistical mechanics was established. Overall, in this thesis some nascent concepts regarding disorder and chaos were investigated to efficiently manage electromagnetic waves in optoelectronic devices.

Light extraction

Light trapping

Quantifying disorder

Solid-state lighting

Energy harvesting

Microscopic Chaos

Light Extraction Enhancement of GaN Based LEDs Using Top Gratings, Patterned Sapphire Substrates, and Reflective Surfaces

Chavoor, Greg

01 June 2012

In the last 15 years, an immense amount of research has gone into developing high efficiency Gallium Nitride based light emitting diodes (LED). These devices have become increasingly popular in LED displays and solid state lighting. Due to the large difference in refractive index between GaN and Air, a significant amount of light reflects at the boundary and does not escape the device. This drawback decreases external quantum efficiency (EQE) by minimizing light extraction. Scientists and engineers continue to develop creative solutions to enhance light extraction. Some solutions include surface roughening, patterned sapphire substrates, and reflective layers. This study proposes to increase external quantum efficiency and optimize light extraction efficiency of several LED structures using finite difference time domain analysis (FDTD). The structures under investigation include GaN based LEDs with nanoscale top gratings, patterned sapphire substrates in combination with SiO2 nanorod arrays, and reflective surfaces below and above the sapphire substrate. First, we optimize GaN based nanoscale top gratings and increase light extraction by 17.8%. Next, we simulate ITO based top gratings and enhance light extraction by 40%. Third, we optimize patterned sapphire substrate period and width and the vertical position of a SiO2 nanorod array. We achieve as high as 51.8% improvement in light extraction. Finally, we increase light extraction by 160% with the use of a silver reflection layer.

GaN

Reflection Layer

Patterned Sapphire Substrate

Ag

Light Extraction

Electromagnetics and Photonics

Optimisation de l’extraction de lumière de scintillation dans les matrices de détecteurs pixellisés pour des applications en tomographie d’émission par positrons (TEP) et en tomodensitométrie (TDM) / Optimization of the extraction of scintillation light in pixelated detector arrays for applications in positron emission tomography (PET) and computed tomography (CT)

Loignon-Houle, Francis

January 2016

Résumé : Les performances de détecteurs à scintillation, composés d’un cristal scintillateur couplé à un photodétecteur, dépendent de façon critique de l’efficacité de la collecte et de l’extraction des photons de scintillation du cristal vers le capteur. Dans les systèmes d’imagerie hautement pixellisés (e.g. TEP, TDM), les scintillateurs doivent être arrangés en matrices compactes avec des facteurs de forme défavorables pour le transport des photons, au détriment des performances du détecteur. Le but du projet est d’optimiser les performances de ces détecteurs pixels par l'identification des sources de pertes de lumière liées aux caractéristiques spectrales, spatiales et angulaires des photons de scintillation incidents sur les faces des scintillateurs. De telles informations acquises par simulation Monte Carlo permettent une pondération adéquate pour l'évaluation de gains atteignables par des méthodes de structuration du scintillateur visant à une extraction de lumière améliorée vers le photodétecteur. Un plan factoriel a permis d'évaluer la magnitude de paramètres affectant la collecte de lumière, notamment l'absorption des matériaux adhésifs assurant l'intégrité matricielle des cristaux ainsi que la performance optique de réflecteurs, tous deux ayant un impact considérable sur le rendement lumineux. D'ailleurs, un réflecteur abondamment utilisé en raison de ses performances optiques exceptionnelles a été caractérisé dans des conditions davantage réalistes par rapport à une immersion dans l'air, où sa réflectivité est toujours rapportée. Une importante perte de réflectivité lorsqu'il est inséré au sein de matrices de scintillateurs a été mise en évidence par simulations puis confirmée expérimentalement. Ceci explique donc les hauts taux de diaphonie observés en plus d'ouvrir la voie à des méthodes d'assemblage en matrices limitant ou tirant profit, selon les applications, de cette transparence insoupçonnée. / Abstract : The performance of scintillation detectors, made up of a scintillating crystal coupled to a photodetector, critically depends on the collection and extraction efficiency of scintillation photons from the crystal by the sensor. In highly pixelated imaging systems (e.g. PET, CT), scintillators must be arranged in compact arrays with form factors detrimental to light transport, deteriorating the detector performance. The goal of the study was to optimize the pixelated detectors performance by identifying the light loss sources related to the spectral, spatial and angular characteristics of the scintillation photons impinging on scintillators faces. Such information acquired by Monte Carlo simulations enables adequate weighting for the evaluation of achievable gains through structuring of the scintillators for enhanced light extraction to the photodetector. The magnitude of parameters affecting the light collection in arrays, such as adhesive materials absorption and reflector opacity that both have high impact on light output, was evaluated through a factorial design. A frequently used reflector because of its outstanding optical performance was characterized in more realistic conditions compared to air immersion in which its reflectivity is always reported. An important reflectivity quenching of the reflector in optically bonded scintillator arrays was discovered by simulation and confirmed experimentally. This explains the high light crosstalk measured in pixelated arrays as well as paving the way to assembling methods limiting or taking advantage, depending on the application, of this unsuspected transparency.

Tomographie d'émission par positrons

Tomodensitométrie

Scintillateur

Propagation de lumière

Extraction de lumière

Positron emission tomography

Light collection

Light extraction

CT

Scintillators

Optical Simulation and Optimization of Light Extraction Efficiency for Organic Light Emitting Diodes

January 2016

abstract: Current organic light emitting diodes (OLEDs) suffer from the low light extraction efficiency. In this thesis, novel OLED structures including photonic crystal, Fabry-Perot resonance cavity and hyperbolic metamaterials were numerically simulated and theoretically investigated. Finite-difference time-domain (FDTD) method was employed to numerically simulate the light extraction efficiency of various 3D OLED structures. With photonic crystal structures, a maximum of 30% extraction efficiency is achieved. A higher external quantum efficiency of 35% is derived after applying Fabry-Perot resonance cavity into OLEDs. Furthermore, different factors such as material properties, layer thicknesses and dipole polarizations and locations have been studied. Moreover, an upper limit for the light extraction efficiency of 80% is reached theoretically with perfect reflector and single dipole polarization and location. To elucidate the physical mechanism, transfer matrix method is introduced to calculate the spectral-hemispherical reflectance of the multilayer OLED structures. In addition, an attempt of using hyperbolic metamaterial in OLED has been made and resulted in 27% external quantum efficiency, due to the similar mechanism of wave interference as Fabry-Perot structure. The simulation and optimization methods and findings would facilitate the design of next generation, high-efficiency OLED devices. / Dissertation/Thesis / Masters Thesis Mechanical Engineering 2016

Mechanical engineering

Electromagnetics

Optics

Fabry-Perot

FDTD

Interference effect

Light Extraction Efficiency

Optical Simulation

Organic Light Emitting Diode

Black-box optimization of simulated light extraction efficiency from quantum dots in pyramidal gallium nitride structures

Olofsson, Karl-Johan

January 2019

Microsized hexagonal gallium nitride pyramids show promise as next generation Light Emitting Diodes (LEDs) due to certain quantum properties within the pyramids. One metric for evaluating the efficiency of a LED device is by studying its Light Extraction Efficiency (LEE). To calculate the LEE for different pyramid designs, simulations can be performed using the FDTD method. Maximizing the LEE is treated as a black-box optimization problem with an interpolation method that utilizes radial basis functions. A simple heuristic is implemented and tested for various pyramid parameters. The LEE is shown to be highly dependent on the pyramid size, the source position and the polarization. Under certain circumstances, a LEE over 17% is found above the pyramid. The results are however in some situations very sensitive to the simulation parameters, leading to results not converging properly. Establishing convergence for all simulation evaluations must be done with further care. The results imply a high LEE for the pyramids is possible, which motivates the need for further research.

Black-box optimization

Radial basis functions

Gallium nitride

light extraction efficiency

FDTD

surrogate functions

semiconductors

global optimization

Computational Mathematics

Beräkningsmatematik

Křemíkové nanokrystaly, fotonické struktury a optický zisk / Silicon nanocrystals, photonic structures and optical gain

Ondič, Lukáš

January 2014

Silicon nanocrystals (SiNCs) of sizes below approximately 5 nm are a material with an efficient room-temperature photoluminescence (PL) and optical gain. Optical gain is a pre- requisite for obtaining stimulated emission from a pumped material, and the achievement of stimulated emission (and lasing) from Si-based nanostructures is of particular interest of the field of silicon photonics. The aim of this work was (i) to investigate fundamental optical properties of SiNCs, (ii) to design and prepare a photonic crystal with enhanced light ex- traction efficiency and (iii) to explore a possibility of enhancing optical gain of light-emitting SiNCs by combining them with a two-dimensional photonic crystal. First, free-standing oxide (SiOx/SiO2)-passivated SiNCs were prepared by electrochemical etching of a Si wafer. Their optical properties were studied by employing time-resolved spectroscopy, also at cryogenic temperatures. The fast blue-green emission band of these SiNCs was linked with the quasi- direct recombination of hot electrons and holes in the vicinity of the Γ-point. Furthermore, the spectral shift of the slow orange-red band (of these SiNCs) as a function of temperature was explained on the basis of an interplay between tensile strain and bulk Si temperature-induced indirect bandgap shift. The...

Analysis of Light Extraction Efficiency Enhancement for Deep Ultraviolet and Visible Light-Emitting Diodes with III-Nitride Micro-Domes

Zhao, Peng

12 March 2013

No description available.

Electrical Engineering

Optics

III-nitride light-emitting diodes

light extraction efficiency

deep ultraviolet

thin-film flip-chip

micro-domes

Extraction de la lumière par des nanoparticules métalliques enterrées dans des films minces / Light extraction in dielectric thin-films using embedded metallic nanoparticles

Jouanin, Anthony

24 July 2014

L’essor des procédés de micro et nano-fabrications rend aujourd’hui accessible la synthèse contrôlée de nanoparticules métalliques (typiquement de 3 à 200nm) offrant de larges résonances d’absorption et de diffusion dont les fréquences peuvent être contrôlées finement en variant judicieusement leur géométrie et leur composition. Dans ce travail de thèse relevant de l’électrodynamique classique établit par Maxwell, nous étudions numériquement l’intérêt de ces particules pour la problématique du (dé)couplage de la lumière piégée dans un film mince diélectrique - une géométrie de référence permettant de rendre compte du phénomène de piégeage qui limite considérablement l’efficacité de dispositifs électroluminescents et de certaines cellules solaires. Pour ce faire, nous proposons quelques règles de conception de nanoparticules capables d’extraire efficacement la lumière piégée. Pour un émetteur seul, environ 20% de la lumière émise est rayonnée hors du guide (rad~0.2). L’ajout d’une monocouche (~50nm d’épaisseur) composée d’un ensemble de particules « optimisées » et aléatoirement positionnées autour de l’émetteur permet d’accroître cette efficacité jusqu’à 70% en moyenne statistique sur le désordre. D’intéressants effets de cohérences liés à la nature du désordre au sein de ladite couche sont également mis en évidence. / Metallic nanoparticles (MNps) exhibit strong plasmonic resonances in their absorption and scattering spectra. Recent advances in micro- and nano-fabrication processes allow scientists to control the particle shape; and thus to tune these resonances on the visible and near-IR spectrum - opening unprecedented applications ranging from imaging techniques to solar cells improvement. In the present work, we numerically investigate the capacity of MNps to (de)couple the light that is confined in guided modes of dielectric thin films—a relevant system to analyze, understand and reduce the light trapping phenomenon that strongly lowers the efficiency of some electroluminescent devices. To this end, we propose, by the control of its polarization state, to optimize the quantity of light that a nanoparticle extracts during a scattering event. For a sole source embedded in the guide, barely 20% of the light is extracted (rad~0.2). The addition of an ultra-thin layer composed of hundreds of randomly deposited engineered-nanoparticles shows promising results with rad ~0.7 (in realistic configurations). Interesting coherence effects arising from the randomness of the disorder are also evidenced.

Extraction

Ag-Nanoparticules

Résonance plasmonique de surface

Oled

Couplage

Transfert radiatif

Light extraction

Silver nanoparticles

Plasmonics

Oled

Light coupling

Radiative transfer

530.141

530.2

530.3

530.4