Selective ablation with UV lasers of a-Si:H thin film solar cells in direct scribing configuration

Monolithical series connection of silicon thin-film solar cells modules performed by laser scribing plays a very important role in the entire production of these devices. In the current laser process interconnection the two last steps are developed for a configuration of modules where the glass is essential as transparent substrate. In addition, the change of wavelength in the employed laser sources is sometimes enforced due to the nature of the different materials of the multilayer structure which make up the device. The aim of this work is to characterize the laser patterning involved in the monolithic interconnection process in a different configurations of processing than the usually performed with visible laser sources. To carry out this study, we use nanosecond and picosecond laser sources working at 355nm of wavelength in order to achieve the selective ablation of the material from the film side. To assess this selective removal of material has been used EDX (energy dispersive using X-ray) analysis

Practical issues for testing thin film PV modules at standard test conditions.

Thin film photovoltaic (TF) modules have gained importance in the photovoltaic (PV) market. New PV plants increasingly use TF technologies. In order to have a reliable sample of a PV module population, a huge number of modules must be measured. There is a big variety of materials used in TF technology. Some of these modules are made of amorphous or microcrystalline silicon. Other are made of CIS or CdTe. Not all these materials respond the same under standard test conditions (STC) of power measurement. Power rates of the modules may vary depending on both the extent and the history of sunlight exposure. Thus, it is necessary a testing method adapted to each TF technology. This test must guarantee repeatability of measurements of generated power. This paper shows responses of different commercial TF PV modules to sunlight exposure. Several test procedures were performed in order to find the best methodology to obtain measurements of TF PV modules at STC in the easiest way. A methodology for indoor measurements adapted to these technologies is described.

Analysis by finite element calculations of light scattering in laser-textured AZO films for PV thin-film solar cells

In the thin-film photovoltaic industry, to achieve a high light scattering in one or more of the cell interfaces is one of the strategies that allow an enhancement of light absorption inside the cell and, therefore, a better device behavior and efficiency. Although chemical etching is the standard method to texture surfaces for that scattering improvement, laser light has shown as a new way for texturizing different materials, maintaining a good control of the final topography with a unique, clean, and quite precise process. In this work AZO films with different texture parameters are fabricated. The typical parameters used to characterize them, as the root mean square roughness or the haze factor, are discussed and, for deeper understanding of the scattering mechanisms, the light behavior in the films is simulated using a finite element method code. This method gives information about the light intensity in each point of the system, allowing the precise characterization of the scattering behavior near the film surface, and it can be used as well to calculate a simulated haze factor that can be compared with experimental measurements. A discussion of the validation of the numerical code, based in a comprehensive comparison with experimental data is included.

First principles study of Bi dopen CdTe thin film solar cells: electronic and optical properties

Nowadays, efficiency improvement of solar cells is one of the most important issues in photovoltaic systems and CdTe is one of the most promising thin film photovoltaic materials we can found. CdTe reported efficiencies in solar energy conversion have been as good as that found in polycrystalline Si thin film cell [1], besides CdTe can be easily produced at industrial scale.

Ultra high frequency thin film saw devices

Durante los últimos años el flujo de datos en la transmisión que tiene lugar en los sistemas de comunicación ha aumentado considerablemente de forma que día a día se requieren más aplicaciones trabajando en un rango de frecuencias muy alto (3-30 GHz). Muchos de estos sistemas de comunicación incluyen dispositivos de onda acústica superficial (SAW) y por tanto se hace necesario el aumento de frecuencia a la que éstos trabajan. Pero este incremento de frecuencia de los dispositivos SAW no sólo es utilizado en los sistemas de comunicación, varios tipos de sensores, por ejemplo, aumentan su sensibilidad cuando la frecuencia a la que trabajan también lo hace. Tradicionalmente los dispositivos SAW se han fabricado sobre cuarzo, LiNbO3 y LiTaO3 principalmente. Sin embargo la principal limitación de estos materiales es su velocidad SAW. Además, debido a la alta temperatura a la que se depositan no pueden ser integrados en la tecnología de fabricación CMOS. El uso de la tecnología de capa delgada, en la que un material piezoeléctrico es depositado sobre un substrato, se está utilizando en las últimas décadas para incrementar la velocidad SAW de la estructura y poder obtener dispositivos trabajando en el rango de frecuencias requerido en la actualidad. Por otra parte, esta tecnología podría ser integrada en el proceso de fabricación CMOS. Durante esta tesis nos hemos centrado en la fabricación de dispositivos SAW trabajando a muy alta frecuencia. Para ello, utilizando la tecnología de capa delgada, hemos utilizado la estructura nitruro de aluminio (AlN) sobre diamante que permite conseguir velocidades SAW del sustrato que no se pueden alcanzar con otros materiales. El depósito de AlN se realizó mediante sputtering reactivo. Durante esta tesis se han realizado diferentes experimentos para optimizar dicho depósito de forma que se han obtenido los parámetros óptimos para los cuales se pueden obtener capas de AlN de alta calidad sobre cualquier tipo de sustrato. Además todo el proceso se realizó a baja temperatura para que el procesado de estos dispositivos pueda ser compatible con la tecnología CMOS. Una vez optimizada la estructura AlN/diamante, mediante litografía por haz de electrones se fabricaron resonadores SAW de tamaño nanométrico que sumado a la alta velocidad resultante de la combinación AlN/diamante nos ha permitido obtener dispositivos trabajando en el rango de 10-28 GHz con un alto factor de calidad y rechazo fuera de la banda. Estás frecuencias y prestaciones no han sido alcanzadas por el momento en resonadores de este tipo. Por otra parte, se han utilizado estos dispositivos para fabricar sensores de presión de alta sensibilidad. Estos dispositivos son afectados altamente por los cambios de temperatura. Se realizó también un exhaustivo estudio de cómo se comportan en temperatura estos resonadores, entre -250ºC y 250ºC (rango de temperaturas no estudiado hasta el momento) diferenciándose dos regiones una a muy baja temperatura en la que el dispositivo muestra un coeficiente de retraso en frecuencia (TCF) relativamente bajo y otra a partir de los -100ºC en la que el TCF es similar al observado en la bibliografía. Por tanto, durante esta tesis se ha optimizado el depósito de AlN sobre diamante para que sea compatible con la tecnología CMOS y permita el procesado de dispositivos trabajando a muy alta frecuencia con altas prestaciones para comunicaciones y sensores. ABSTRACT The increasing volume of information in data transmission systems results in a growing demand of applications working in the super-high-frequency band (3–30 GHz). Most of these systems work with surface acoustic wave (SAW) devices and thus there is a necessity of increasing their resonance frequency. Moreover, sensor application includes this kind of devices. The sensitivity of them is proportional with its frequency. Traditionally, quartz, LiNbO3 and LiTaO3 have been used in the fabrication of SAW devices. These materials suffer from a variety of limitations and in particular they have low SAW velocity as well as being incompatible with the CMOS technology. In order to overcome these problems, thin film technology, where a piezoelectric material is deposited on top of a substrate, has been used during the last decades. The piezoelectric/substrate structure allows to reach the frequencies required nowadays and could be compatible with the mass electronic production CMOS technology. This thesis work focuses on the fabrication of SAW devices working in the super-high-frequency range. Thin film technology has been used in order to get it, especially aluminum nitride (AlN) deposited by reactive sputtering on diamond has been used to increase the SAW velocity. Different experiments were carried out to optimize the parameters for the deposit of high quality AlN on any kind of substrates. In addition, the system was optimized under low temperature and thus this process is CMOS compatible. Once the AlN/diamond was optimized, thanks to the used e-beam lithography, nanometric SAW resonators were fabricated. The combination of the structure and the size of the devices allow the fabrication of devices working in the range of 10-28 GHz with a high quality factor and out of band rejection. These high performances and frequencies have not been reached so far for this kind of devices. Moreover, these devices have been used as high sensitivity pressure sensors. They are affected by temperature changes and thus a wide temperature range (-250ºC to 250ºC) study was done. From this study two regions were observed. At very low temperature, the temperature coefficient of frequency (TCF) is low. From -100ºC upwards the TCF is similar to the one appearing in the literature. Therefore, during this thesis work, the sputtering of AlN on diamond substrates was optimized for the CMOS compatible fabrication of high frequency and high performance SAW devices for communication and sensor application.

Transport properties of CuGaSe(2)-based thin-film solar cells as a function of absorber composition

The transport properties of thin-film solar cells based on wide-gap CuGaSe(2) absorbers have been investigated as a function of the bulk [Ga]/[Cu] ratio ranging from 1.01 to 1.33. We find that (i) the recombination processes in devices prepared from absorbers with a composition close to stoichiometry ([Ga]/[Cu] = 1.01) are strongly tunnelling assisted resulting in low recombination activation energies (E(a)) of approx. 0.95 eV in the dark and 1.36 eV under illumination. (ii) With an increasing [Ga]/[Cu] ratio, the transport mechanism changes to be dominated by thermally activated Shockley-Read-Hall recombination with similar E(a) values of approx. 1.52-1.57 eV for bulk [Ga]/[Cu] ratios of 1.12-1.33. The dominant recombination processes take place at the interface between CdS buffer and CuGaSe(2) absorber independently from the absorber composition. The increase of E(a) with the [Ga]/[Cu] ratio correlates with the open circuit voltage and explains the better performance of corresponding solar cells.

Characterization of thin film PV modules under standard test conditions: Results of indoor and outdoor measurements and the effects of sunlight exposure

Photovoltaic modules based on thin film technology are gaining importance in the photovoltaic market, and module installers and plant owners have increasingly begun to request methods of performing module quality control. These modules pose additional problems for measuring power under standard test conditions (STC), beyond problems caused by the temperature of the module and the ambient variables. The main difficulty is that the modules’ power rates may vary depending both on the amount of time they have been exposed to the sun during recent hours and on their history of sunlight exposure. In order to assess the current state of the module, it is necessary to know its sunlight exposure history. Thus, an easily accomplishable testing method that ensures the repeatability of the measurements of the power generated is needed. This paper examines different tests performed on commercial thin film PV modules of CIS, a-Si and CdTe technologies in order to find the best way to obtain measurements. A method for obtaining indoor measurements of these technologies that takes into account periods of sunlight exposure is proposed. Special attention is paid to CdTe as a fast growing technology in the market.

International Materials Science Seminars: A Bridge between Two Continents

International Materials Science Seminars aim at combining the expertise of several advanced research groups and creating an unique opportunity for foreign and Spanish students in terms of cutting-edge research.

New strategies in laser processing of TCOs for light management improvement in thin-film silicon solar cells

Light confinement strategies play a crucial role in the performance of thin-film (TF) silicon solar cells. One way to reduce the optical losses is the texturing of the transparent conductive oxide (TCO) that acts as the front contact. Other losses arise from the mismatch between the incident light spectrum and the spectral properties of the absorbent material that imply that low energy photons (below the bandgap value) are not absorbed, and therefore can not generate photocurrent. Up-conversion techniques, in which two sub-bandgap photons are combined to give one photon with a better matching with the bandgap, were proposed to overcome this problem. In particular, this work studies two strategies to improve light management in thin film silicon solar cells using laser technology. The first one addresses the problem of TCO surface texturing using fully commercial fast and ultrafast solid state laser sources. Aluminum doped Zinc Oxide (AZO) samples were laser processed and the results were optically evaluated by measuring the haze factor of the treated samples. As a second strategy, laser annealing experiments of TCOs doped with rare earth ions are presented as a potential process to produce layers with up-conversion properties, opening the possibility of its potential use in high efficiency solar cells.

Size and dimensionality effects in superconducting Mo thin films

Molybdenum is a low Tc, type I superconductor whose fundamental properties are poorly known. Its importance as an essential constituent of new high performance radiation detectors, the so-called transition edge sensors (TESs) calls for better characterization of this superconductor, especially in thin film form. Here we report on a study of the basic superconducting features of Mo thin films as a function of their thickness. The resistivity is found to rise and the critical temperature decreases on decreasing film thickness, as expected. More relevant, the critical fields along and perpendicular to the film plane are markedly different, thickness dependent and much larger than the thermodynamic critical field of Mo bulk. These results are consistent with a picture of type II 2D superconducting films, and allow estimates of the fundamental superconducting lengths of Mo. The role of morphology in determining the 2D and type II character of the otherwise type I molybdenum is discussed. The possible consequences of this behaviour on the performance of radiation detectors are also addressed

Electronic property analysis of O-doped Cu3SbS3

The ternary Cu-Sb-S semiconductors are considered to be sustainable and potential alternative absorber materials in thin film photovoltaic applications. In these compounds, several phases may coexist, albeit in different proportions depending on experimental growth conditions. Additionally, the photovoltaic efficiency could be increased with isoelectronic doping. In this work we analyze the electronic properties of O-doped Cu3SbS3 in two structures: the wittichenite and the skinnerite. We use first-principles within the density functional formalism with two different exchange-correlation potentials. In addition, we estimate the potential of these compounds for photovoltaic applications.

Fatigue in laser shock peened open-hole thin aluminium specimens

An experimental study was performed in order to determine the influence of the sequence of operations on the effectiveness of Laser Shock Peening (LSP) treatment in increasing the fatigue performances of open-hole aluminium specimens. Residual stress measurements, fractographic analysis and FEM analysis were performed, indicating the presence of compressive residual stresses on the surface of the treated specimens and tensile residual stresses in the mid-section along the thickness of the specimens. Negative effects on fatigue lives were encountered on the specimens with the hole already present, while positive effect were observed in specimens in which the hole was drilled after LSP treatment. These results indicate that LSP can be a good solution for “in production” application, in which open holes are to be drilled after the LSP treatment. The application in which LSP is used “in service” on structures with pre-existing cut-outs, has proven to be impracticable in the investigated configuration.

Interconexión monolítica de módulos fotovoltaicos de silicio amorfo en lámina delgada sobre vidrio mediante ablación láser en régimen de nanosegundos

Esta tesis se centra en el estudio de una secuencia de procesos basados en la tecnología láser y ejecutados en dispositivos fotovoltaicos, que son imprescindibles para el desarrollo en general de las tecnologías fotovoltaicas basadas en lámina delgada y, en particular, de aquellas que utilizan silicio amorfo como absorbente, así como en aplicaciones posteriores de estas tecnologías de alto valor añadido como es la integración arquitectónica de este tipo de dispositivos. En gran parte de las tecnologías FV de lámina delgada, y muy particularmente en la de silicio amorfo, el material se deposita sobre un substrato en un área lo suficientemente grande para que se requiera de un proceso de subdivisión del dispositivo en células de tamaño adecuado, y su posterior conexión en serie para garantizar las figuras eléctricas nominales del dispositivo. Este proceso se ha desarrollado industrialmente hace años, pero no ha habido un esfuerzo científico asociado que permitiera conocer en profundidad los efectos que los procesos en si mismos tiene de forma individualizada sobre los materiales que componen el dispositivo y sus características finales. Este trabajo, desarrollado durante años en el Centro Láser de la UPM, en estrecha colaboración con Centro de Investigaciones Energéticas y Medioambientales (CIEMAT), la Universidad de Barcelona (UB), y la Universidad Politécnica de Cataluña (UPC), se centra justamente en un estudio detallado de dichos procesos, denominados habitualmente P1, P2, P3 y P4 atendiendo al orden en el que se realizan en el dispositivo. Este estudio incluye tanto la parametrización de los procesos, el análisis del efecto que los mismos producen sobre los materiales que componen el dispositivo y su comportamiento fotoeléctrico final, así como la evaluación del potencial uso de fuentes láser de última generación (ultrarrápidas) frente al estándar industrial en la actualidad que es el empleo de fuentes láser convencionales de ancho temporal en el rango de los nanosegundos. En concreto se ha estudiado en detalle las ventajas y limitaciones del uso de sistemas con diferentes rangos espectrales (IR, VIS y UV) y temporales (nanosegundos y picosegundos) para diferentes tipos de configuraciones y disposiciones tecnológicas (entendiendo por estas las habituales configuraciones en substrato y superestrato de este tipo de dispositivos). La caracterización individual de los procesos fue realizada primeramente en células de laboratorio específicamente diseñadas, abriendo nuevos planteamientos y conceptos originales para la mejora de los procesos láser de interconexión y posibilitando el empleo y desarrollo de técnicas y métodos avanzados de caracterización para el estudio de los procesos de ablación en las distintas láminas que conforman la estructura de los dispositivos fotovoltaicos, por lo que se considera que este trabajo ha propuesto una metodología completamente original, y que se ha demostrado efectiva, en este ámbito. Por último el trabajo aborda un tema de particular interés, como es el posible uso de los procesos desarrollados, no para construir los módulos fotovoltaicos en sí, sino para personalizarlos en forma y efectos visuales para potenciar su uso mediante elementos integrables arquitectónicamente, lo que es un ámbito de gran potencial de desarrollo futuro de las tecnologías fotovoltaicas de lámina delgada. En concreto se presentan estudios de fabricación de dispositivos integrables arquitectónicamente y plenamente funcionales no solo en dispositivos de silicio amorfo con efectos de transparencias y generación de formas libres, si no que también se incluye la posibilidad de hacer tales dispositivos con células de silicio cristalino estándar que es la tecnología fotovoltaica de mayor presencia en mercado. Es importante, además, resaltar que la realización de este trabajo ha sido posible gracias a la financiación obtenida con dos proyectos de investigación aplicada, MICROSIL (PSE-120000-2008-1) e INNDISOL (IPT-420000-2019-6), y los correspondientes al Plan Nacional de I+D+I financiados por el ministerio de Ciencia e Innovación y el Ministerio de Economía y Competitividad: CLÁSICO (ENE 2007- 67742-C04-04) y AMIC ENE2010-21384-C04-02. De hecho, y en el marco de estos proyectos, los resultados de este trabajo han ayudado a conseguir algunos de los hitos más importantes de la tecnología fotovoltaica en nuestro país en los últimos años, como fue en el marco de MICROSIL la fabricación del primer módulo de silicio amorfo con tecnología íntegramente española (hecho en colaboración con el CIEMAT), o la fabricación de los dispositivos para integración arquitectónica con geometrías libres que se describen en esta Tesis y que fueron parte de los desarrollos del proyecto INNDISOL. ABSTRACT This thesis focuses on the study of a sequence of laser-based technology and processes executed in photovoltaic devices, which are essential for the overall development of photovoltaic technologies based on thin film and, in particular, those using amorphous silicon as absorbent and subsequent applications of these technologies with high added value such as the architectural integration of such devices. In much of the PV thin film technologies, and particularly in the amorphous silicon material is deposited on a substrate in an area large enough so that it requires a process of subdivision of the device in cells of appropriate size, and subsequent serial connection to ensure nominal device power figures. This process has been industrially developed years ago, but there has been an associate scientific effort that would learn more about the effects that the processes themselves have either individually on the materials that make up the device and its final characteristics. This work, developed over years in the Laser Center of the UPM, in close collaboration with Centre for Energy and Environmental Research (CIEMAT), the University of Barcelona (UB) and the Polytechnic University of Catalonia (UPC)., Focuses precisely in a detailed study of these processes, usually they called P1, P2, P3 and P4 according to the order in which they perform on the device. This study includes both the parameters of the processes, the analysis of the effect they produce on the materials making up the device and its final photoelectric behavior as well as the potential use of EVALUATION of next-generation laser sources (ultrafast) versus standard industry today is the use of conventional laser sources temporal width in the range of nanoseconds. In particular we have studied in detail the advantages and limitations of using systems with different spectral ranges (IR, UV and VIS) and time (nanosecond and picosecond) for different configurations and technological provisions (meaning these typical configurations in substrate and superstrate such devices). Individual characterization of the processes was conducted primarily in laboratory cells specifically designed, opening new approaches and original concepts for improving laser interconnection processes and enabling the use and development of advanced techniques and characterization methods for studying the processes ablation in the different sheets making up the structure of the photovoltaic devices, so it is considered that this work has proposed a completely original methodology, which has proven effective in this area. Finally, the paper addresses a topic of particular interest, as is the possible use of lso developed processes, not to build the photovoltaic modules themselves but to customize fit and visual effects to enhance their use by integrated architectural elements, which is an area of great potential for future development of thin film photovoltaic technologies. Specifically studies manufacture of integrated architecturally and fully functional not only in amorphous silicon devices with transparency effects and generating freeform devices occur, if not also include the ability to make such devices with cells of standard crystalline silicon photovoltaic technology is more visible in the market. It is also important to note that the completion of this work has been possible thanks to the financing obtained with two applied research projects, Microsil (PSE-120000- 2008-1) and INNDISOL (IPT-420000-2019-6), and those for the National R & D funded by the Ministry of Science and Innovation and the Ministry of Economy and Competitiveness: CLASSIC (ENE 2007-67742-C04-04) and AMIC ENE2010-21384-C04- 02. In fact, within the framework of these projects, the results of this work have helped get some of the most important milestones of photovoltaic technology in our country in recent years, as it was under Microsil making the first module Amorphous silicon technology with entirely Spanish (made in collaboration with CIEMAT), or the manufacture of devices for architectural integration with free geometries that are described in this thesis and that were part of the project Inndisol developments.

Inorganic Photovoltaics - Planar and Nanostructured Devices

Since its invention in the 1950s, semiconductor solar cell technology has evolved in great leaps and bounds. Solar power is now being considered as a serious leading contender for replacing fossil fuel based power generation. This article reviews the evolution and current state, and potential areas of near future research focus, of leading inorganic materials based solar cells, including bulk crystalline, amorphous thin-films, and nanomaterials based solar cells. Bulk crystalline silicon solar cells continue to dominate the solar power market, and continued efforts at device fabrication improvements, and device topology advancements are discussed. III-V compound semiconductor materials on c-Si for solar power generation are also reviewed. Developments in thin-film based solar cells are reviewed, with a focus on amorphous silicon, copper zinc tin sulfide, cadmium telluride, as well as nanostructured Cadmium telluride. Recent developments in the use of nano-materials for solar power generation, including silicon and gallium arsenide nanowires, are also reviewed.