Synthèse et modélisation de polyfullèrenes / Synthesis and modeling of polyfullerenes

Santos Silva, Hugo

16 July 2015

Les travaux développés au cours de cette thèse comprennent le dessin, modélisation, synthèse et caractérisation de nouveaux matériaux polymérisés à base de fullèrene. Dans le cadre d'une utilisation au sein de cellules photovoltaïques, ces matériaux doivent démontrer propriétés telles que solubilité dans des solvants organiques, miscibilité avec le polymère absorbeur de lumière et stabilité morphologique supérieures à celles rencontrées pour les matériaux déjà en utilisation, tels les (bis-)PC60BM et les dérivés d'indene-C60. Six routes de synthèse différentes ont été étudiées et les propriétés électroniques (énergie de LUMO, électroaffinité, électrophylicité, énergies de réorganisation, intégrale de transfert et mobilité électronique) qui en résultent ont été déterminées par des méthodologies de modélisation numérique. Parmi ces composés modèles, la route dite ATRAP a été retenue pour être synthétisée vue qu'elle a été peu étudiée dans la littérature. Les propriétés physico-chimiques de ces composés synthétisés avec des différentes chaînes latérales ont été déterminées par plusieurs techniques et leur application dans des couches minces au sein des dispositifs photovoltaïques a été mise en place. Quand utilisés comme additifs, ces matériaux présentent un potentiel de stabilisation de la couche de P3HT/PC60BM, vu que la performance des cellules qui l'ont est très peu affectée. Le comportement de ces couches sous traitement thermique a montré un effet de non-stabilisation dont le mécanisme a été, lui aussi, étudié par diverses techniques expérimentales. Finalement, un mécanisme de dépolymérisation induit par lumière et/ou chaleur a été proposé. Selon ceci, la cassure de la liaison chimique entre le monomère et le fullèrene est responsable pour la création des défauts, dépolymérisation, cross-linkings et réarrangement irréversible de la couche mince. Cette cassure peut être soit thermiquement activée, soit par l'état triplet du monomère qui déstabilise cette même liaison. Outre que l'étude de ces composés, la stabilisation de l'interface organique-inorganique en dispositifs photovoltaïques, la stabilisation de la chaîne latérale des polymères conjugués et la relation entre affinité avec oxygène moléculaire et la géométrie de la molécule en question ont été adressées. Ces études parallèles ont été achevées par la proposition de nouveaux matériaux hybrides du type donneur-accepteur dérivés de hexabenzocoronene capables de s'empiler dans des structures similaires à des cristaux liquides discotiques. À partir des connaissances acquises au cours de ce document, deux composés ont été proposés et leurs propriétés électroniques montrent qu'il est possible de dessiner des matériaux qui peuvent être, à la fois, stables et efficaces pour être utilisés dans le domaine du photovoltaïque organique. / The work developed during this thesis include the design, modeling, synthesis and characterization of new polymeric materials based on fullerenes. In the optics of a use within photovoltaic cells, these materials have to present particular properties, among which a good solubility in organic solvents, a good miscibility with the light-absorber polymer as well as a morphological stability superior to those currently used materials, such as (bis-)PC60BM and the derivatives of indene-C60. Six different synthetic routes were studied and the electronic properties (LUMO orbital energy, electroaffinity, electrophilicity, reorganization energy, transfer integral and electron mobility) risen were determined by molecular modeling. Among these routes, the one called ''ATRAP'', not much studied in the literature yet, was finally retained. The physical-chemical properties of the so-synthesized materials, grafted with different lateral chains, were determined by different characterization techniques and their application in thin films for Organic Photovoltaic devices was performed. When used as additives, these materials display a potential of stabilizing the P3HT/PC60BM layer, and this does not influence the performance of the device. After a thermal treatment, this behavior was the opposite of the expected, though: a destabilization of the active layer was noted which mechanism was also studied by several experimental techniques. Finally, a depolymerization mechanism induced by light and/or heat was proposed. Within this process, the cleavage of the monomer-fullerene bond is responsible for creating defects, such as the depolymerization, cross-linkings or irreversible rearrangement of the thin layer. This cleavage can be either thermally activated or induced by the triplet state of the monomer, which also destabilizes this bond. Beyond that, this work was also interested i) to the stabilization of the organic-inorganic interface within photovoltaic devices, ii) to the stabilization of the lateral chain of conjugated polymers, as well as iii) the relation between the geometry of a carbon-based molecule and its reactivity to molecular oxygen. These studies, performed in parallel, drove to the proposition of new donor-acceptor hybrid materials based on hexabenzocoronene, which are capable of stacking over itself to form supramolecular structures similar to discotic liquid crystals. From the conclusions of this document, two products were proposed, which electronic properties reveal that it is possible to design new materials that may be stable and efficient at the same time for application in organic photovoltaics.

Fullèrenes

Photovoltaïque organique

Stabilité

Modélisation

Synthèse.

Fullerenes

Organic photovoltaics

Stability

Modeling

Synthesis.

Efficiency-Limiting Recombination Mechanisms in High-Quality Crystalline Silicon for Solar Cells

January 2018

abstract: Recent technology advancements in photovoltaics have enabled crystalline silicon (c-Si) solar cells to establish outstanding photoconversion efficiency records. Remarkable progresses in research and development have been made both on the silicon feedstock quality as well as the technology required for surface passivation, the two dominant sources of performance loss via recombination of photo-generated charge carriers within advanced solar cell architectures. As these two aspects of the solar cell framework improve, the need for a thorough analysis of their respective contribution under varying operation conditions has emerged along with challenges related to the lack of sensitivity of available characterization techniques. The main objective of my thesis work has been to establish a deep understanding of both “intrinsic” and “extrinsic” recombination processes that govern performance in high-quality silicon absorbers. By studying each recombination mechanism as a function of illumination and temperature, I strive to identify the lifetime limiting defects and propose a path to engineer the ultimate silicon solar cell. This dissertation presents a detailed description of the experimental procedure required to deconvolute surface recombination contributions from bulk recombination contributions when performing lifetime spectroscopy analysis. This work proves that temperature- and injection-dependent lifetime spectroscopy (TIDLS) sensitivity can be extended to impurities concentrations down to 109 cm-3, orders of magnitude below any other characterization technique available today. A new method for the analysis of TIDLS data denominated Defect Parameters Contour Mapping (DPCM) is presented with the aim of providing a visual and intuitive tool to identify the lifetime limiting impurities in silicon material. Surface recombination velocity results are modelled by applying appropriate approaches from literature to our experimentally evaluated data, demonstrating for the first time their capability to interpret temperature-dependent data. In this way, several new results are obtained which solve long disputed aspects of surface passivation mechanisms. Finally, we experimentally evaluate the temperature-dependence of Auger lifetime and its impact on a theoretical intrinsically limited solar cell. These results decisively point to the need for a new Auger lifetime parameterization accounting for its temperature-dependence, which would in turn help understand the ultimate theoretical efficiency limit for a solar cell under real operation conditions. / Dissertation/Thesis / Doctoral Dissertation Materials Science and Engineering 2018

Materials Science

Energy

Engineering

defects

photovoltaics

recombination

silicon

solar cells

surface passivation

Comparison of Encapsulant Degradation between Glass/Backsheet and Glass/Glass Field-aged Photovoltaic Modules

January 2018

abstract: Ethylene vinyl acetate (EVA) is the most commonly used encapsulant in photovoltaic modules. However, EVA degrades over time and causes performance losses in PV system. Therefore, EVA degradation is a matter of concern from a durability point of view. This work compares EVA encapsulant degradation in glass/backsheet and glass/glass field-aged PV modules. EVA was extracted from three field-aged modules (two glass/backsheet and one glass/glass modules) from three different manufacturers from various regions (cell edges, cell centers, and non-cell region) from each module based on their visual and UV Fluorescence images. Characterization techniques such as I-V measurements, Colorimetry, Different Scanning Calorimetry, Thermogravimetric Analysis, Raman spectroscopy, and Fourier Transform Infrared Spectroscopy were performed on EVA samples. The intensity of EVA discoloration was quantified using colorimetric measurements. Module performance parameters like Isc and Pmax degradation rates were calculated from I-V measurements. Properties such as degree of crystallinity, vinyl acetate content and degree of crosslinking were calculated from DSC, TGA, and Raman measurements, respectively. Polyenes responsible for EVA browning were identified in FTIR spectra. The results from the characterization techniques confirmed that when EVA undergoes degradation, crosslinking in EVA increases beyond 90% causing a decrease in the degree of crystallinity and an increase in vinyl acetate content of EVA. Presence of polyenes in FTIR spectra of degraded EVA confirmed the occurrence of Norrish II reaction. However, photobleaching occurred in glass/backsheet modules due to the breathable backsheet whereas no photobleaching occurred in glass/glass modules because they were hermetically sealed. Hence, the yellowness index along with the Isc and Pmax degradation rates of EVA in glass/glass module is higher than that in glass/backsheet modules. The results implied that more acetic acid was produced in the non-cell region due to its double layer of EVA compared to the front EVA from cell region. But, since glass/glass module is hermetically sealed, acetic acid gets entrapped inside the module further accelerating EVA degradation whereas it diffuses out through backsheet in glass/backsheet modules. Hence, it can be said that EVA might be a good encapsulant for glass/backsheet modules, but the same cannot be said for glass/glass modules. / Dissertation/Thesis / Masters Thesis Chemical Engineering 2018

Chemical engineering

Materials Science

Alternative energy

characterization

degradation

encapsulant

field-aged

photovoltaics

reliability

Case Study of Photovoltaics and Electric Vehicle Charging in a Low-Voltage Distribution Grid

Gustafsson, Anton

January 2019

This thesis investigates the effects from a grid connection of photovoltaics and electric vehicle charging in a low-voltage distribution grid. The study has taken place on behalf of Norrtälje Energi AB, and the object of study is a customer in one of their rural grids. Due to reported disturbances by the customer, a Magtech Voltage Booster (MVB) was installed at the point of common coupling. To evaluate the situation, three power quality measurements were analysed. Furthermore, a model of the distribution grid was developed in OpenDSS. The main conclusion of this thesis is that the disturbances seems to be caused by temporary voltage drops (below 195.5 V) during charging hours. This situation continues to create problems even though the MVB boosts and balances the voltage. The power quality measurements showed that the voltage unbalance, during charging hours, violated the limit both before and after the MVB-installation. Another significant conclusion in this thesis is that the MVB does not seem to improve the power quality, on the contrary it deteriorates the power quality with regards to rapid voltage change and harmonic content. Furthermore, the OpenDSS-model was able to predict the temporary voltage drops. And the model also resulted in voltage unbalance comparable to the measurements. The model also displayed how the voltage unbalance and harmonic content mitigated to other parts of the grid, and it became clear that it is only the closest neighbour that is in the risk of deteriorated power quality.

Power quality

photovoltaics

electric vehicle

distribution grid

OpenDSS

Engineering and Technology

Teknik och teknologier

Incorporation of Gold Nanowires into Photovoltaic Devices

Gordon, Scott W

23 May 2019

To this day, fossil fuels still make up over 80% of the earth’s energy production. Many sources of renewable energy are available, but photovoltaics is the only source with the capacity proven to meet the increasing world energy needs. Third generation devices such as dye-sensitized and organic solar cells have gained much interest due to their cost effectiveness and flexibility but have yet to become commercially viable. Here methods have been studied to improve these devices with the use of Gold nanowire arrays. These additions provide plasmonic and light scattering enhancements in dye-sensitized solar cells. Different TiO2 deposition methods have been studied to protect the gold from the redox couple in the electrolyte. Several novel methods have been undertaken to incorporate gold nanowire arrays in organic solar cells with some success. Structural characterization shows the proposed architecture is achieved, but working devices met suffered from low success rate.

dye-sensitized solar cells

organic photovoltaics

gold nanowire arrays

Materials Chemistry

Optimization Of The Two Stage Process For Cu(In,Ga)Se₂ Solar Cells

Pethe, Shirish

08 July 2004

Copper Indium Gallium DiSelenide absorber layers are fabricated using a two stage manufacturing friendly process. The first step involves the sequential deposition of Copper and Gallium and co-deposition of indium and selenium at 275oC. This is followed by the second stage where the substrate is annealed in the presence of Selenium and a thin layer of copper is deposited to neutralize the excess Indium and Gallium on the surface to form the CIGS absorber layer. The top copper thickness as well as the time of deposition was varied to study the effect of Copper on the performance of the cells. Another recipe was developed for the precursor formation, where Gallium was co-evaporated with Indium and Selenium. A large bandgap shift was seen with this recipe and the open circuit voltage was increased. The performance of CIGS/CdS/ZnO solar cells thus fabricated was characterized using techniques like I-V, C-V, Spectral Response and EDS/SEM. Cells with open circuit voltages of 420-450 mV, short circuit currents of 33-38 mA/cm², fill factors of 58-62% and efficiencies of 9-11% were routinely fabricated.

cigs

photovoltaics

absorber layer

co-evaporation

cis

American Studies

Arts and Humanities

Characterization Of Large Area Cadmium Telluride Films And Solar Cells Deposited On Moving Substrates By Close Spaced Sublimation

Kumar, Vishwanath

12 November 2003

With CdTe based photovoltaics developed by close spaced sublimation reaching efficiencies of over 16%, commercialization of this technology draws serious attention. Today large area industrial modules have not been able to produce the same performance of their laboratory counterparts. This work provides a means for understanding the various technical challenges in developing an effective deposition technology for large area processing. The submodule process investigated provides a model for continuous and sequential processing of subsequent films. The system has a unique design and constructed with the provision for a moving transport module for the substrate transport. The process was developed to deposit large area CdTe (3 x 3 sq. inch) and provides valuable insights for the development of a large area deposition system. Upon optimizing the system for reproducibility, proper deposition conditions were established. Films deposited under various conditions were studied to improve our understanding of the influence of processing conditions on device performance. The key advantage of this technique over others is its high deposition rate, simplicity of operation and high conversion efficiency. Typical deposition times were two minutes and could be reduced to as low as 45 sec with little variation in performance. The four major parameters that influence the films prepared by close spaced sublimation, namely substrate temperature, source temperature, ambient pressure, and spacing were optimized for best device performance. The influence of each parameter on deposition rate and cell efficiency was also studied. The best cells produced by this technology had an efficiency of 13% with Voc=830 mV, FF= 74% and Jsc=21.1 mA/cm2.

Photovoltaics

II-VI semiconductors

thin films

vacuum processing

American Studies

Arts and Humanities

Caractérisation théorique de la dynamique de processus de transfert de charge au sein d'architectures de type donneur-espaceur-accepteur

Van Vooren, Antoine

28 September 2009

Les réactions de transfert de charge entre molécules sont des processus fondamentaux dans de nombreux domaines scientifiques. En particulier, elles sont responsables de la conversion de la lumière en énergie chimique (photosynthèse) ou en énergie électrique dans les cellules solaires organiques (domaine du photovoltaïque). Ces dernières visent à produire de l’électricité à coût réduit afin de contribuer aux besoins en énergie renouvelable. Leur rendement reste toutefois faible (environ 5-6% contre 25% pour les cellules à base de silicium) et leur amélioration requiert l’optimisation de chaque étape du processus de transformation de l’énergie lumineuse en courant électrique : absorption de la lumière ; dissociation des excitations ; séparation des charges ; transport des charges. Les processus de dissociation d’excitations, de transport de charge, ainsi que de recombinaison de charges (diminuant le rendement de la cellule solaire) impliquent tous des réactions de transfert d’électron. Les transistors à effet de champ sont des composants fondamentaux en électronique, utilisés comme interrupteurs, déterminant si le courant passe ou non. Les transistors organiques se posent comme alternative moins couteuse aux transistors à base de silicium. Comme dans les cellules solaires, les processus de transfert de charge sont d’une importance primordiale, gouvernant ici la mobilité des charges au sein du dispositif. Rendre les dispositifs d’électroniques organiques concurrentiels par rapport aux dispositifs inorganiques nécessite de les rendre plus performants. Cette amélioration des performances passe, entre autres, par une optimisation des processus de transfert de charge. Dans ce contexte, cette thèse porte sur une étude théorique, basée sur des méthodes de chimie quantique et de mécanique moléculaire, de systèmes donneur-pont-accepteur, dans le but de mieux comprendre les processus de transfert de charge au sein de ces systèmes, en vue de leur utilisation en électronique organique. Ces systèmes présentent plusieurs avantages pour les cellules solaires : le fait de lier chimiquement le donneur et l’accepteur réduit la ségrégation de phase et la séparation des charges est facilitée lorsque les charges sont formées loin l’une de l’autre (grâce à la présence du pont) car l’attraction de Coulomb entre charges générées est réduite. Des molécules pontées peuvent également avoir d’autres applications, comme par exemple l’amélioration de la mobilité des charges dans un transistor organique à effet de champ en permettant un transport entre couches moléculaires. Nous nous sommes intéressés dans un premier temps à des structures modèles afin de mieux comprendre les mécanismes fondamentaux associés aux processus à transfert de charge. Nous avons ensuite appliqué cette méthode à trois types de systèmes réels, synthétisés et caractérisés expérimentalement. La première étude concerne le transport de charge au sein d’un copolymère conjugué donneur/accepteur, F8BT. La seconde concerne l’utilisation de systèmes pontés en vue d’une utilisation dans des transistors à effets de champs organiques. La dernière concerne l’injection de charges dans un matériau organique conjugué via une couche mono-moléculaire auto-assemblée. Pour terminer, nous nous sommes intéressés à l’influence de la dynamique structurale (vibrations moléculaires) sur les vitesses des réactions de transfert de charge dans des systèmes donneur-pont-accepteur.

solar cells

photovoltaics

molecular dynamics

electron transfer

charge transfer

quantum chemistry

Plasmonic Manipulation of Light for Sensing and Photovoltaic Applications

January 2012

Plasmonics is a successful new field of science and technology that exploits the exclusive optical properties of metallic nanostructures to manipulate and concentrate light at nano-meter length scales. When light hits the surface of gold or silver nanoparticles it can excite collective oscillations of the conduction electrons called surface plasmons. This surface plasmon undergoes two damping processes; it can decay into photon and reemit the plasmon energy as scattered energy or decay into electron-hole pair with the excitation energy equal to the energy of the plasmon resonance, known as absorption. This high energy electron subsequently undergoes into the carrier multiplication and eventually scatters into the electrons with lower energy. We used Finite-Difference Time-Domain (FDTD) and Finite-Element Method (Comsol) to design nanoscale structures to act as nanoantenna for light harvesting and consequently manipulating radiative and absorption properties of them for Sensing and Photovoltaic applications. To manipulate near and far field we designed our structures in a way that the bright and dark plasmon modes overlap and couple to each other. This process is called Fano resonance and introduces a transparency window in the far-field spectra. At the same time it increases the near-field enhancement. We applied the changes in near-field and far-field to SERS (Surface Enhanced Raman Spectroscopy) and LSPR (Localized Surface plasmon Resonance) shift for sensing purposes. We modeled Fano resonances with classical harmonic oscillator and reproduced the same feature with a simple equation of motion. We used this model to replicate scattering spectra from different geometries and explain the cathodoluminescence results obtained from nanoscale gold clusters structure. All of these nanoantenna optical properties and applications are due to the reemission ability of the plasmon energy to the vacuum and confining optical field, but the plasmon energy can decay into a high energy carrier rather than radiation. Photons coupled into metallic nanoantenna excite resonant plasmons, which can decay into energetic, hot electrons injected over a potential barrier at the nanoantenna-semiconductor interface, resulting in a photocurrent. We design a device which the range of its potential applications is extremely diverse. As silicon based detector capable of detecting sub-band gap photons, this device could be used in photovoltaic devices to harvest solar energy. Plasmon generated hot electrons can be used in photocatalytic dissociation of H2 molecules at the room temperature as well. The hot electrons in their higher energy states can populate the antibonding orbital of H2 molecules adsorbed on the metal surface and thus trigger the H2 molecule dissociation. The goal is to demonstrate the high efficiency of metallic photocatalytic systems by detecting the formation of HD molecules from the individual dissociation of two isotopes, H2 and D2. At the end we introduce lightning rod effect in metallic nanostructures and investigated the relation between the geometry properties of micrometer rod antennas and the electromagnetic field enhancement induced due to the lightning rod effect. At long wavelength, metals behave like perfect equipotential conductors and all the field enhancement results from the drop of potentials across the junctions between individual nanoparticles. This phenomenon is called lightning rod effect. By designing proper geometry we were able to utilize this effect to obtain enough electromagnetic enhancements in MIR region of spectrum to observe SEIRA signals from few hemoglobin molecules. Our simulation shows that the field enhancement obtained from this antenna does not depend sensitively on wavelength which is another advantage for SEIRA spectroscopy. We offered an analytical model to explore the coupling between the hemoglobin molecules and the Efield. We used this model to study the location effect of the molecule on the reflection signal. This technique allows us to detect the vibrational mode of molecules such as Hemoglobin in the real time and study their changes when the molecules are exposed to different environmental circumstances.

Applied sciences

Pure sciences

Photovoltaics

Nanophotonics

Light manipulation

Electrical engineering

Nanoscience

Nanotechnology

Optics

Fabrication and Characterization of Nanowires and Quantum Dots for Advanced Solar Cell Architectures

Sadeghimakki, Bahareh

January 2012

The commercially available solar cells suffer from low conversion efficiency due to the thermalization and transmission losses arising from the mismatch between the band gap of the semiconductor materials and the solar spectrum. Advanced device architectures based on nanomaterial have been proposed and being successfully used to enhance the efficiency of the solar cells. Quantum dots (QDs) and nanowires (NWs) are the nanosclae structures that have been exploited for the development of the third generation solar cell devices and nanowire based solar cells, respectively. The optical and electrical properties of these materials can be tuned by their size and geometry; hence they have great potential for the production of highly efficient solar cell. Application of QDs and NWs with enhanced optoelectronic properties and development of low-cost fabrication processes render a new generation of economic highly efficient PV devices. The most significant contribution of this PhD study is the development of simple and cost effective methods for fabrication of nanowires and quantum dots for advanced solar cell architectures. In advanced silicon nanowires (SiNWs) array cell, SiNWs have been widely synthesised by the well-known vapor-liquid-solid method. Electron beam lithography and deep reactive ion etching have also been employed for fabrication of SiNWs. Due to the high price and complexity of these methods, simple and cost effective approaches are needed for the fabrication of SiNWs. In another approach, to enhance the cell efficiency, organic dyes and polymers have been widely used as luminescent centers and host mediums in the luminescent down shifting (LDS) layers. However, due to the narrow absorption band of the dyes and degradation of the polymers by moisture and heat, these materials are not promising candidates to use as LDS. Highly efficient luminescent materials and transparent host materials with stable mechanical properties are demanded for luminescent down shifting applications. In this project, simple fabrication processes were developed to produce SiNWs and QDs for application in advanced cell architectures. The SiNWs array were successfully fabricated, characterized and deployed in new cell architectures with radial p-n junction geometry. The luminescence down shifting of layers containing QDs in oxide and glass mediums was verified. The silica coated quantum dots which are suitable for luminescence down shifting, were also fabricated and characterized for deployment in new design architectures. Silicon nanowires were fabricated using two simplified methods. In the first approach, a maskless reactive ion etching process was developed to form upright ordered arrays of the SiNWs without relying on the complicated nano-scale lithography or masking methods. The fabricated structures were comprehensively characterized. Light trapping and photoluminescence properties of the medium were verified. In the second approach, combination of the nanosphere lithography and etching techniques were utilized for wire formation. This method provides a better control on the wire diameters and geometries in a very simple and cost effective way. The fabricated silicon nanowires were used for formation of the radial p-n junction array cells. The functionality of the new cell structures were confirmed through experimental and simulation results. Quantum dots are promising candidates as luminescent centers due to their tunable optical properties. Oxide/glass matrices are also preferred as the host medium for QDs because of their robust mechanical properties and their compatibility with standard silicon processing technology. Besides, the oxide layers are transparent mediums with good passivation and anti-reflection coating properties. They can also be used to encapsulate the cell. In this work, ordered arrays of QDs were incorporated in an oxide layer to form a luminescent down shifting layer. This design benefits from the enhanced absorption of a periodic QD structure in a transparent oxide. The down shifting properties of the layer after deployment on a crystalline silicon solar cell were examined. For this purpose, crystalline silicon solar cells were fabricated to use as test platform for down shifting. In order to examine the down-shifting effect, different approaches for formation of a luminescence down shifting layer were developed. The LDS layer consist of cadmium selenide- zinc sulfide (CdSe/ZnS) quantum dots in oxide and glass layers to act as luminescent centers and transparent host medium, respectively. The structural and optical properties of the fabricated layers were studied. The concept of spectral engineering was proved by the deployment of the layer on the solar cell. To further benefit from the LDS technique, quantum efficiency of the QDs and optical properties of the layer must be improved. Demand for the high quantum efficiency material with desired geometry leaded us to synthesis quantum dots coated with a layer of grown oxide. As the luminescence quantum efficiency of the QDs is correlated to the surface defects, one advantage of having oxide on the outer shell of the QDs, is to passivate the surface non-radiative recombination centers and produce QDs with high luminescent quantum yield. In addition, nanoparticles with desired size can be obtained only by changing the thickness of the oxide shell. This method also simplifies the fabrication of QD arrays for luminescence down shifting application, since it is easier to form ordered arrays from larger particles. QD superlattices in an oxide medium can be fabricated on a large area by a simple spin-coating or dip coating methods. The photonic crystal properties of the proposed structure can greatly increase the absorption in the QDs layer and enhance the effect of down shifting.

Semiconductor

Solar cell

Quantum dot

Nanowire

Down-shifting

Synthesis

Photovoltaics

Fabrication

Characterization

Electrical and Computer Engineering