Effect of DC to DC converters on organic solar cell arrays for powering DC loads

Trotter, Matthew S.

26 February 2009

The objective of this research is to determine if it is possible to reduce the number of organic solar cells required to power a load using a DC to DC converter thereby reducing the cost of the organic solar array system. An organic solar power system designer may choose an organic implementation of a DC to DC converter to go along with the organic solar cell array. Common DC to DC converters include the buck converter, boost converter, buck/boost converter, and Cuk converter, all of which are not good candidates for organic implementation due to their use of inductors. Organic inductors are relatively more lossy than organic capacitors. So, an inductor-less DC to DC converter, such as the Dickson charge pump, would be a better candidate for organic implementation. Solar cells connected in an array configuration usually do not perform up to their full potential due to current and voltage mismatches between solar cells. These mismatches can be related to each solar cell's circuit model parameters such as the photon current density, diode ideality factor, diode reverse saturation current density, parallel resistance, and series resistance. This research varies these circuit model parameters as dependent variables, and observes the loads and power levels that make the Dickson charge pump a feasible option. The results show that current mismatch does produce an opportunity to use a DC to DC converter to save the use of a few solar cells. However, the Dickson charge pump was found to be infeasible due to an input voltage requirement that could not be met using the tested organic solar cells.

DC to DC converters

Charge pumps

Organic solar cells

Solar cells

Dickson charge pump

Solar batteries

DC-to-DC converters

Organic electronics

Σύνθεση και μελέτη υβριδικών φωτοβολταϊκών κυττάρων : νέα πρόκληση για το περιβάλλον και τα κτίρια

Τρυπαναγνωστοπούλου, Μαρία

16 June 2011

Η διπλωματική μεταπτυχιακή εργασία ειδίκευσης παρουσιάζει μελέτη σε φωτοευαισθητοποιημένα ηλιακά κύτταρα, τα οποία μετατρέπουν την ηλιακή ακτινοβολία σε ηλεκτρική ενέργεια. Στο θεωρητικό μέρος παρουσιάζεται βιβλιογραφική ανασκόπηση των φωτοβολταϊκών κυττάρων και γίνεται εμβάθυνση στον μηχανισμό λειτουργίας των φωτοευαισθητοποιημένων ηλιακών κυττάρων με χρωστική ουσία (Dye-sensitized Solar Cells, DSSC). Αναλύονται τα υλικά που χρησιμοποιούνται για την σύνθεση του ηλιακού κυττάρου: υποστρώματα από Indium-Tin Oxide (ITO), υμένιο από νανο-κρυσταλλικό διοξείδιο του τιτανίου (TiO2), οργανικές χρωστικές ουσίες, υγρός/στερεός ηλεκτρολύτης ιωδίου και αντιηλεκτρόδιο. Επιπλέον, περιγράφονται πειραματικές διατάξεις από ελληνικά και διεθνή εργαστήρια τα οποία παρουσιάζουν τις νέες εξελίξεις στον τομέα των φωτοευαίσθητων φωτοβολταϊκών. Στο πειραματικό μέρος περιγράφεται η διαδικασία σύνθεσης φωτοευαίσθητων ηλιακών κυττάρων στο εργαστήριο. Γίνεται μελέτη των επιμέρους υλικών και σύνθεση νέων ηλιακών κυττάρων, έτσι ώστε να επιτευχθεί αύξηση της απόδοσης και της σταθερότητας των υποστρωμάτων τους. Σύμφωνα με την θεωρία Shockley–Queisser, η μέγιστη θεωρητική απόδοση ενός ηλιακού κυττάρου φτάνει το 30% και με επόμενες παρόμοιες μεθόδους υπολογίσθηκε ότι μπορεί να φτάσει το 68%. Παρουσιάζονται επιπλέον, πειραματικές διατάξεις με εφαρμογή χαμηλοδιάστατου ημιαγωγού, με σκοπό την αύξηση της απόδοσης και ταυτόχρονα την μείωση του υλικού και του κόστους του φωτοβολταϊκού. Η μελέτη και ο χαρακτηρισμός των επιμέρους υλικών έγινε με την χρήση τεχνικών οργάνων, όπως: XRD, UV, PL, SEM. Η μέτρηση της απόδοσης των ηλιακών κυττάρων πραγματοποιήθηκε σε εσωτερικό σκοτεινό χώρο με προσομοίωση του ηλιακού φωτός με την χρήση του ηλεκτρομέτρου και υπολογίστηκαν οι αποδόσεις των φωτοβολταϊκών κυττάρων. / The present master thesis presents a study on photo-sensitized solar cells, which convert solar radiation into electricity. The theoretical part includes a literature of relevant works on solar cells and a description of the operation mechanism of photo-sensitized solar cells using pigment (Dye-sensitized solar cells, DSSC). The materials used for the fabrication of solar cell were Indium-Tin Oxide (ITO) for the substrate, thin film from nanoparticles of titanium dioxide (TiO2), organic pigments, liquid/solid iodide electrolyte and counter electrode. In addition, testing devices and cell fabrication procedures, from national and international laboratories covering the developments in the field of photosensitive solar cells, are also included. In the experimental part, the procedure for the synthesis of photo-sensitized solar cells is extensively described. The used materials and the synthesis mode to achieve new cell types with increased efficiencies and substrate stability are presented. According to Shockley-Queisser theory, the theoretically maximum efficiency of solar cell is up to 30%, which in other methods it has been extended to 68%. In the same part, experimental procedures for other semiconductor application are additionally presented, aiming to a reduction in material and cost. The study and the characterization of the used materials were performed by using suitable equipment as XRD, UV, PL and SEM. The solar cell efficiency was measured in a dark room using electrometer and the efficiency were obtained.

Φωτοβολταϊκά κύτταρα

621.381 542 2

Photo-sensitized solar cells

Dye-sensitized solar cells (DSSC)

Photovoltaic cells

Βέλτιστες ηλεκτρικές παράμετροι φωτοβολταϊκών πλαισίων για γήινες και διαστημικές εφαρμογές

Γεωργίτσας, Βασίλειος

04 October 2011

Σκοπός αυτής της διπλωματικής εργασίας είναι η θεωρητική μελέτη φωτοβολταϊκών πλαισίων χρησιμοποιούμενων σε διαστημικές εφαρμογές, περιγράφοντας την τεχνολογία και τη λειτουργία τους, καθώς και την ιστορική εξέλιξη τους τις τελευταίες δεκαετίες από το 1950 έως σήμερα. Στα πλαίσια αυτά περιγράφονται οι ηλιακές συστοιχίες για διαστημικές εφαρμογές, οι συνηθισμένοι τύποι ημιαγωγικών υλικών για τα πλαίσια, όπως το πυρίτιο Si και το αρσενιούχο γάλλιο GaAs και οι απαιτήσεις των. Αρχικά, μελετάται ποιες παράμετροι επηρεάζουν την απόδοση των φωτοβολταϊκών κυττάρων στο διάστημα και επιπλέον οι επιπτώσεις της διαστημικής ακτινοβολίας και θερμοκρασίας στην λειτουργία των πλαισίων. Στη συνέχεια παρουσιάζονται τα προηγμένα ηλιακά κύτταρα πυριτίου Si και τα υψηλής απόδοσης άμορφου πυριτίου που παρουσιάζουν βελτιωμένη ενεργειακή απόδοση του πλαισίου. Οι βέλτιστες παράμετροι των δομών για τις διαστημικές εφαρμογές, φαίνεται πλέον να επιτυγχάνονται με τα ευρέως χρησιμοποιούμενα ηλιακά κύτταρα πολυεπαφών multijunction MJ, που είναι κύτταρα ιδιαιτέρου τρόπου σχεδιασμού. Οι παράμετροι επηρεασμού της απόδοσης τους αναλύονται καθώς και οι επιπτώσεις των εξωτερικών συνθηκών. Μεγάλης σημασίας θεωρείται ο σχεδιασμός της ηλιακής συστοιχίας στο διάστημα και οι απαιτήσεις σχεδίασης για αξιόπιστη απόδοση και μεγάλη διάρκεια ζωής. Στη μελέτη αυτή αναλύουμε και τις δομές εκείνες που μπορούν να βελτιώσουν την απόδοση των διαστημικών ηλιακών κυττάρων. Οι πιο ελπιδοφόρες και πιο πολλά υποσχόμενες δομές είναι αυτές των μεταμορφικών «metamorphic» και ανεστραμμένων μεταμορφικών «inverted-metamorphic» ηλιακών κυττάρων σε σχέση με τα κλασικά "latticed matched" ηλιακά κύτταρα και αυτες οι δομές θα συνεχίσουν να βρίσκονται στο επίκεντρο για τις επόμενες δεκαετίες. Επιπλέον προϊόν της παρούσας διπλωματικής εργασίας, είναι η πειραματική μελέτη της συμπεριφοράς ενός φωτοβολταϊκού πλαισίου μονοκρυσταλλικού πυριτίου m-Si ισχύος αιχμής 80 W σε πραγματικές συνθήκες λειτουργίας στη γη, υπό την επίδραση διαφόρων εξωτερικών παραγόντων, όπως προσπίπτουσα ακτινοβολία, θερμοκρασία και γωνία κλίσης. Με στόχο την εκτίμηση της ενεργειακής απόδοσης και της ανίχνευσης της βέλτιστης τιμής αυτής πραγματοποιήθηκαν μετρήσεις με την βοήθεια του PVPM στη διάρκεια του έτους 2009 – 2010. Συγκεκριμένα περιλαμβάνονται δυο περίοδοι μετρήσεων: α) Απρίλιος 2009 έως Ιούλιος 2009, όπου πραγματοποιήθηκαν μετρήσεις ανά μια ώρα για όλες τις γωνίες κλίσης 0, 10, 20, 30, 40, 50, 60, 70, 80ο (μια ημέρα κάθε εβδομάδα) με την βοήθεια της ρυμθιζόνεμης βάσης και β) Αύγουστος 2009 έως Μάρτιος 2010, όπου πραγματοποιήθηκαν ολοήμερες μετρήσεις ανά 5 λεπτά, κάθε εβδομάδα με την βοήθεια φορητού υπολογιστή σε συγκεκριμένη κλίση 38ο, που αντιστοιχεί στο γεωγραφικό πλάτος της περιοχής της Πάτρας. Όλα αυτά οδηγούν σε μια ολοκληρωμένη εικόνα της ενεργειακής συμπεριφοράς και απόδοσης του φωτοβολταϊκού πλαισίου μας καθώς και των συνθηκών που οδηγούν σε βέλτιστες φωτοβολταϊκές ιδιότητες Η ετήσια αποδιδόμενη ενέργεια υπολογίστηκε ελαφρώς υψηλότερη από μετρήσεις γενικά αναφερόμενες από το ΚΑΠΕ. Αυτό θεωρούμε ότι οφείλεται στο γεγονός ότι η διάταξη μας δεν κατέγραφε μετρήσεις καθ όλη τη διάρκεια του έτους με αποτέλεσμα να μην είναι ακριβής η διάρκεια της ημέρας και η τιμή της προσπίπτουσας ηλιακής ακτινοβολίας. Μέσω του PVsyst προγράμματος προσπαθήσαμε να προσομοιώσουμε την ενεργειακή απόδοση του πλαισίου μονοκρυσταλλικού πυριτίου υπολογιστικά τόσο με τα πειραματικά μετεωρολογικά δεδομένα όσο και με τα μετεωρολογικά δεδομένα μέσω του προγράμματος Meteonorm και να την συγκρίνουμε με την πειραματική και επιπλέον να βρούμε την βέλτιστη απόδοση του ανάλογα με την κλίση και τον προσανατολισμό του. Η εξομοίωση με δεδομένα του προγράμματος Meteonorm 6.1 έδωσε τη διαφορά της αποδιδόμενης ενέργειας κάθε περίπτωσης, μεταξύ αυτής και της προηγούμενης μεθόδου. / The purpose of this thesis, is the theoretical study of solar modules used in space applications, together with the description of their technology and operation, and the historical development in recent decades from 1950 to today. In this context we analyzed the solar arrays for space applications, the requirements of materials for solar cells and the common types of semiconductor materials for modules, such as silicon Si and gallium arsenide GaAs. Initially, we studied what external factors affect the performance of solar cells in space and also the effects of space radiation and temperature. Further, we described the advanced silicon solar cells and the high-efficiency amorphous silicon solar cells, that improve the energy efficiency significant. For the optimal solution for space applications, we then analyzed thoroughly the most widely used in space multijunction MJ solar cells and their design, the performance parameters and the effects of external factors. To summarize the theoretical study, we studied the design of the solar array in space and the design requirements for reliable performance and longevity. Finally, there are many ways we can improve the performance of space solar cells. The most promising methods are those of metamorphic «metamorphic» and reverse metamorphic «inverted-metamorphic» solar cells compared to the classic "latticed matched" solar cells and will continue to be in the forefront for decades to come. Additional to the subject of this thesis, is the experimental study of the behavior of a photovoltaic monocrystalline silicon module m-Si 80 W peak power at real operation conditions under the influence of various external factors such as incident radiation, temperature and tilt. In order to estimate the energy efficiency we took measurements with the help of PVPM in the year 2009 - 2010. Specifically, it consists of two measurement periods: a) April 2009 to July 2009, when measurements were taken every hour for all angles 0, 10, 20, 30, 40, 50, 60, 70, 80 every week with the help of special structure and b) August 2009 to March 2010, when measurements were made all day, every five minutes, each week with a notebook in a particular inclination 38ο, corresponding to the latitude of the region of Patras. All these help us to gain a comprehensive idea of their behavior and performance of our photovoltaic modules. We also observed variation in the results in comparison with CRES databases due to the fact that we could not continuously conduct every day of the year. Using PVsyst we tried to verify our experimental results and find the best solutions for the tilt and orientation of the PV modules. With the program PVsyst we tried to simulate the performance of monocrystalline silicon solar cell using computational frameworks and to compare them with the experimental results. Finally it was also simulated with the data given from the database of the program Meteronorm 6.1 so as to compare both methods.

Δορυφόροι

621.381 542

Satellites

Space solar cells

Monocrystalline silicon

Multijunction solar cells

Electrical parameters

Photovoltaic module

Modélisation hors-équilibre des cellules solaires : effets quantiques au niveau nanométrique / Nonequilibrium modeling of solar cells : quantum effects at the nanoscale level

Nematiaram, Tahereh

07 June 2017

Un défi mondial fondamental est de développer des technologies peu coûteuses et stables pour récolter efficacement l'énergie solaire et la transformer en formes pratiques. Ainsi pour la conversion photovoltaïque plusieurs générations de cellules solaires ont émergé. En général, on peut diviser les types existants de cellules solaires en deux classes distinctes: les photovoltaïques inorganiques conventionnels (IPV), comme les jonctions silicium p-n, et les cellules solaires excitoniques (XSCs). Selon le type de matériaux utilisés les cellules solaires excitoniques sont classées en deux catégories: les cellules solaires à colorant (DSC) et les cellules organiques (OPV) développées en couche unique, ou en bi-couche, et les hétérojonction en volume (BHJ). Les cellules solaires à base de points quantiques (QDSC) sont un autre type de cellules solaires qui ont une configuration similaire aux DSCs ou OPVs.Bien que la performance des cellules solaires excitoniques ait été un thème central de la communauté scientifique pendant de nombreuses années, des approches théoriques facilitant sa compréhension sont nécessaires. Les théories semi-classiques son inadaptées pour traiter les phénomènes quantiques dans les cellules solaires nano-structurées. De plus, en raison de l'attraction coulombienne entre les porteurs photo-générés, l'application du formalisme de la fonction de Green hors équilibre (NEGF) pose certaines difficultés. Par conséquent, dans cette thèse, nous développons un nouveau formalisme quantique, basé sur la théorie de la diffusion quantique et sur l'équation de Lippmann-Schwinger, pour fournir un cadre complet pour comprendre les processus fondamentaux intervenant dans le fonctionnement des cellules solaires excitoniques.En particulier, nous nous concentrons sur des aspects qui ont été peu pris en compte dans le passé et nous abordons, au travers d’un modèle à deux niveaux, l'interaction Coulombienne électron-trou à courte et à longue portée, la recombinaison électron-trou, l'existence de canaux d'évacuation supplémentaires, le couplage électron phonon et la formation de bandes polaroniques.Ici, les cellules solaires excitoniques à deux niveaux sont considérées dans les régimes permanents et transitoires d'injection de charge. Les photocellules moléculaires où le processus de conversion de l'énergie se déroule dans un seul complexe donneur-accepteur moléculaire attaché aux électrodes sont considérées comme étant représentatives des XSC dans le régime permanent. A titre d'exemple pour les dispositifs photovoltaïques dans le régime transitoire, nous considérons les cellules photovoltaïques organiques hétéro-jonctions massives (BHJ OPV) qui sont l'approche la plus courante des OPV et se composent d'espèces mixtes donneuses et accepteuses. Dans ces systèmes, l'exciton créé par l'absorption des photons dans le côté donneur doit atteindre d'abord l'interface donneur-accepteur. A partir de ce moment, seulement un régime transitoire commence où les charges peuvent être séparées et injectées dans leurs côtés respectifs.Nous démontrons que la séparation du porteur de charge est un processus complexe qui est affecté par différents paramètres, tels que la force de l'interaction électron-trou et le taux de recombinaison non radiative. En outre, en fonction de la structure de la cellule, l'interaction électron-trou peut normalement diminuer ou augmenter anormalement l'efficacité. Le modèle proposé aide à comprendre les mécanismes des cellules solaires excitoniques, et il peut être utilisé pour optimiser leur rendement. / A fundamental global challenge is to develop an inexpensive, stable and scalable technology for efficiently harvesting solar photon energy and converting it into convenient forms. Photovoltaic energy conversion is attracting great attention such that several generations of solar cells have emerged. The existing types of solar cells roughly fall into two distinct classes: conventional inorganic photovoltaics (IPVs), such as silicon p-n junctions, and excitonic solar cells (XSCs). The mechanistic distinction of IPVs and XSCs results in fundamental differences in their photovoltaic behavior.According to the type of materials used in their structure, excitonic solar cells are classified into two categories: dye-sensitized solar cells (DSC) and organic photovoltaics (OPV) developed in single-layer and bi-layer including planar and bulk hetero--junction configurations. Quantum dot solar cells (QDSC) are another type of solar cells that have a similar configurations to DSCs or OPVs.While understanding the performance of excitonic solar cells has been a central effort of the scientific community for many years, theoretical approaches facilitating the understanding of electron-hole interaction and recombination effects on the cell performance are needed. Semiclassical theories are inefficient tools to treat quantum phenomena in nano-structured solar cells, and on the other hand, due to the Coulomb attraction between the photo generated carriers, the application of standard Non-Equilibrium Green Function (NEGF) formalism presents some difficulties although some specific methods allow to circumvent this problem.In this thesis we develop a new quantum formalism, which is based on quantum scattering theory and on the Lippmann-Schwinger equation, to provide a comprehensive framework for understanding the fundamental processes taking place in the operation of excitonic solar cells. Considering simple two-level models we address important effects such as the short--range and long--range electron--hole Coulomb interaction, the electron--hole recombination, the existence of extra evacuation channels, and the electron--phonon coupling and polaronic bands formation.Here, the two-level excitonic solar cells are considered in the permanent and transitory regimes of charge injection. The molecular photocells where the energy conversion process takes place in a single molecular donor-acceptor complex attached to electrodes are considered as a representative of XSCs in the permanent regime. As an example for the photovoltaic devices in the transitory regime, we consider the bulk hetero--junction organic photovoltaic cells (BHJ OPVs) which are the most common approach to OPVs and consists of mixed donor and acceptor species that form interpenetrating connective networks. In these systems the exciton created by the photon absorption in the donor side must reach first the donor--acceptor interface. From this moment only a transitory regime begins where the charges can be separated and injected in their respective sides.We demonstrate that the charge carrier separation is a complex process that is affected by different parameters, such as the strength of the electron--hole interaction and the non--radiative recombination rate. Furthermore, depending on the cell structure, the electron-hole interaction can normally decrease or abnormally increase the cell efficiency. The proposed model helps to understand the mechanisms of excitonic solar cells, and it can be used to optimize their yield.

Modélisation

Hors-Équilibre

Cellules solaires

Solar cell

Excitonic solar cells

Molecular photocells

Bulk hetero-junction organic solar cells

Modeling

Charge separation yiled

530

Interface Engineering and Evaluation of Device Performance in Organic Photovoltaics

Rao, Arun Dhumal

January 2015

In recent years, organic photovoltaics (OPVs) have attracted considerable attention as a potential source of renewable energy over traditional materials due to their light weight, low production cost, mechanically stability and compatibility with flexible substrates in roll to roll processing for high volume production. In the OPVs interface plays an important role in determining the performance of the device. Interface signifies formation of efficient contact with electrode, film, and transport of free charge carrier, which results in better performance in the device. Interface engineering also helps in improving mechanical robustness of the device. Hence, understanding of interface, modification and its evaluation is important in fabrication of efficient device. In this thesis interface is modified such that the performance of the device can be improved (chapter 3 and chapter 4). In Chapter 5 and chapter 6 interface is modified such that device can be fabricated on uncommon substrate. Fabrication of device on uncommon substrates (fiber reinforced plastic and flexible glass substrate), has unique challenges. In chapter 5 and chapter 6, we look at how interface is modified to overcome the challenges associated and also understand the role of interface in improving the performance of device on such substrates is discussed. In Chapter 1 we discuss about working of organic solar cells and the challenges associated in device fabrication. Understanding of interface to overcome challenges associated is explained. It also covers brief introduction to the succeeding chapters discussed in the thesis and its recent developments. To understand the properties of interface and to analyze device performance various characterization techniques have been used are discussed in chapter 2. This chapter also covers the materials and general device fabrication techniques used in this thesis. In chapter 3, a narrow bandgap (NBG) polymer used as a near IR sensitizer in P3HT: PCBM blend. Since, P3HT with a band gap of ~1.9 eV, the commonly used p-type material absorbs approximately ~25 % of incident light. Hence, MP2 (NBG polymer) is used along with P3HT: PCBM in active layer to form a ternary blend, which helps in increased absorption. Basic properties of MP2 are evaluated using UV-visible spectroscopy, differential scanning calaorimetry(DSC), thermogravimetric analyser (TGA), gel permeation chromatography (GPC) and photoluminescence (PL) techniques. To evaluate enhanced absorption of ternary UV-visible spectroscopy is carried out. Charge transfer from one moiety to other in ternary blend is evaluated using PL and Ttime resolved microwave conductivity (TRMC). Morphology of the ternary is assessed using atomic force microscope (AFM) and structural characterization is carried out by X-ray diffraction (XRD). Performance of the device is evaluated by current-voltage (J-V) characterizations. Further improved performance is supported by external quantum efficiency (EQE). Charge extraction with linear increasing voltage (CELIV) of the device is done to evaluate the recombination mechanism in the device and to assess the performance of the device. One-dimensional (1D) ZnO nanostructures provide direct paths for charge transport, and also offer large interfacial area to make them an ideal electron transport layer. In chapter 4 highly aligned ZnO nanorods is used as electron transport layer in OPV. Growth of ZnO nanorods is two-step processes, growing seed layer and growing ZnO nanorods from hydrothermal process using an appropriate seed layer. Two different soft-chemical solution- growth methods (upward and downward) are developed to fabricate self-assembled, oriented ZnO nanorods. Substrate mounting, surface properties and optical transmittance are optimized by varying the nanorods growth conditions. Further the ZnO nanorods are UV ozone treated and its effect on performance of nanostructured buffer layer based device is evaluated. In Chapter 5 OPV is fabricated on an opaque FRP substrate. Fabrication of OPV device on opaque substrate plastic is unique and hence understanding various properties is vital. Such devices fabrication require bottom up approach, with transparent electrode as the top electrode and metal electrode on the surface of FRP. FRP has inherent rough surface of about few microns RMS roughness. In order to reduce the roughness of the substrate FRP was planarized. The planarized layer is chosen, such that it chemically binds with the substrate. The chemical interaction between substrate and planarizing coating is evaluated by FTIR and Raman spectroscopy. The binding of planarized layer and FRP is evaluated using nanoscratch technique and surface energies are studied using contact angle measurements. In addition, adhesion properties of the metal electrodes, which are deposited on planarized FRP are evaluated using nanoscratch technique. Fabrication of OPV requires a top transparent electrode. Simple spin coating technique is used to optimize the top electrode. The property of top electrode is evaluated using UV-visible spectroscopy for transmittance, and sheet resistance of the electrode is characterized. OPV device is fabricated on planarized FRP substrate using optimized top transparent electrode and its PV properties is evaluated. Performance of the device is evaluated for two different bottom electrodes and further performance of device is enhanced using buffer layers. Usually flexible OPVs are fabricated on plastic substrate such as PET, PEN. However they are not structurally stable at high temperatures and have high oxygen and moisture Permeability. In Chapter 6 Organic based photovoltaic devices were fabricated on flexible glass. Flexible glass has high strength and it is also known for low oxygen and moisture permeability. Fabrication of device on flexible glass has never been done before and hence, generation of data is necessary for commercialization of the technology. Device fabrication is optimized by using two different transparent conducting layers (ITO- sputter deposited, PEDOT: PSS-solution processed) and device performance was evaluated for both. Since the substrate is flexible in nature understanding the performance of the device during flexing is important. For this 2-parallel plate flexural apparatus is fabricated for in-situ measurements along with current voltage measurements. These devices are flexed cyclically and performance of device is evaluated. Therefore, work discussed in the thesis show by modifying the interface of the device, and understanding various interfaces of the device is crucial for improving the performance of the device. Also by engineering the interface, devices can be fabricated on various types of substrate.

Organic Photovoltaics

Interface Engineering

Organic Solar cells

Solar Cells

Organic Photovoltaic Devices

Organic Photovoltaic Materials

Organic Electronics

P3HT: PCBM

Organic Solar Cell

ZnO Nanorods

Materials Engineering

Sonochemical Synthesis of Zinc Oxide Nanostructures for Sensing and Energy Harvesting

Vabbina, Phani Kiran

06 July 2016

Semiconductor nanostructures have attracted considerable research interest due to their unique physical and chemical properties at nanoscale which open new frontiers for applications in electronics and sensing. Zinc oxide nanostructures with a wide range of applications, especially in optoelectronic devices and bio sensing, have been the focus of research over the past few decades. However ZnO nanostructures have failed to penetrate the market as they were expected to, a few years ago. The two main reasons widely recognized as bottleneck for ZnO nanostructures are (1) Synthesis technique which is fast, economical, and environmentally benign which would allow the growth on arbitrary substrates and (2) Difficulty in producing stable p-type doping. The main objective of this research work is to address these two bottlenecks and find a solution that is inexpensive, environmentally benign and CMOS compatible. To achieve this, we developed a Sonochemical method to synthesize 1D ZnO Nanorods, core-shell nanorods, 2D nanowalls and nanoflakes on arbitrary substrates which is a rapid, inexpensive, CMOS compatible and environmentally benign method and allows us to grow ZnO nanostructures on any arbitrary substrate at ambient conditions while most other popular methods used are either very slow or involve extreme conditions such as high temperatures and low pressure. A stable, reproducible p-type doping in ZnO is one of the most sought out application in the field of optoelectronics. Here in this project, we doped ZnO nanostructures using sonochemical method to achieve a stable and reproducible doping in ZnO. We have fabricated a homogeneous ZnO radial p-n junction by growing a p-type shell around an n-type core in a controlled way using the sonochemical synthesis method to realize ZnO homogeneous core-shell radial p-n junction for UV detection. ZnO has a wide range of applications from sensing to energy harvesting. In this work, we demonstrate the successful fabrication of an electrochemical immunosensor using ZnO nanoflakes to detect Cortisol and compare their performance with that of ZnO nanorods. We have explored the use of ZnO nanorods in energy harvesting in the form of Dye Sensitized Solar Cells (DSSC) and Perovskite Solar Cells.

Sonochemistry

nanostructures

Zinc Oxide

MoS2

Graphene

Biosensing

Photodetectors

Perovskite Solar cells

Dye sensitized Solar Cells

Biomedical

Electrical and Electronics

Electromagnetics and Photonics

Nanotechnology Fabrication

Characterization Techniques and Optimization Principles for Multi-Junction Solar Cells and Maximum Long Term Performance of CPV Systems

Yandt, Mark

January 2017

Two related bodies of work are presented, both of which aim to further the rapid development of next generation concentrating photovoltaic systems using high efficiency multi junction solar cells. They are complementary since the characterization of commercial devices and the systematic application of design principles for future designs must progress in parallel in order to accelerate iterative improvements. First addressed, is the field characterization of state of the art concentrating photovoltaic systems. Performance modeling and root cause analysis of deviations from the modeling results are critical for bringing reliable high value products to the market. Two complementary tools are presented that facilitate acceleration of the development cycle. The “Dynamic real-time I V Curve Measurement System…” provides a live picture of the current-voltage characteristics of a CPV module. This provides the user with an intuitive understanding of how module performance responds under perturbation. The “Shutter technique for noninvasive individual cell characterization in sealed concentrating photovoltaic modules,” allows the user to probe individual cell characteristics within a sealed module. This facilitates non-invasive characterization of modules that are in situ. Together, these tools were used to diagnose the wide spread failure of epoxy connections between the carrier and the emitter of bypass diodes installed in sealed commercial modules. Next, the optimization principals that are used to choose energy yield maximizing bandgap combinations for multi-junction solar cells are investigated. It is well understood that, due to differences in the solar resource in different geographical locations, this is fundamentally a local optimization problem. However, until now, a robust methodology for determining the influences of geography and atmospheric content on the ideal design point has not been developed. This analysis is presented and the influence of changing environment on the representative spectra that are used to optimize bandgap combinations is demonstrated. Calculations are confirmed with ground measurements in Ottawa, Canada and the global trends are refined for this particular location. Further, as cell designers begin to take advantage of more flexible manufacturing processes, it is critical to know if and how optimization criteria must change for solar cells with more junctions. This analysis is expanded to account for the differences between cells with up to 8 subcell bandgaps. A number of software tools were also developed for the Sunlab during this work. A multi-junction solar cell model calibration tool was developed to determine the parameters that describe each subcell. The tool fits a two diode model to temperature dependent measurements of each subcell and provides the fitting parameters so that the performance of multi-junction solar cells composed of those subcells can be modeled for real world conditions before they are put on-sun. A multi-junction bandgap optimization tool was developed to more quickly and robustly determine the ideal bandgap combinations for a set of input spectra. The optimization process outputs the current results during iteration so that they may be visualized. Finally, software tools that compute annual energy yield for input multi-junction cell parameters were developed. Both a brute force tool that computes energy harvested at each time step, and an accelerated tool that first bins time steps into discrete bins were developed. These tools will continue to be used by members of the Sunlab.

Photovoltaics

Solar Cells

Live IV curve

Shutter Technique

Representative Spectrum

Representative Atmospheric Parameters

Multi Junction Solar Cells

Solar Cell Optimization

Bandgap Optimisation

Concentrating Photovoltaic Systems

Synthesis of Tethering Group on Borylazadipyrromethene Dyes to Apply to Photogalvanic Dye-sensitized Solar Cells

Park, Eunsol

08 1900

This is my thesis research on the preparation of borylazadipyrromethene (azaBODIPY) dyes bearing an anchoring group, such as a carboxylic acid group, at the β-pyrrolic position of the azadipyrromethene scaffold. Carboxylate groups form covalent bonds to oxide semiconductors such as TiO2 (n-type) or Cu2O (p-type) in dye-sensitized solar cells (DSCs) or photogalvanic dye-sensitized solar cells (P-DSCs). Oxide-binding azaBODIPY dyes can be used to investigate the rate and mechanism of electron injection from the dyes to the semiconductors. Two different types of azaBODIPY (difluoroboryl and dialkynylboryl) were prepared by following previously developed methods. To convert difluoroborylazaBODIPY to the final dyes having a carboxylic acid in the β-pyrrolic position, several distinct synthetic routes were designed, adopting various reactions, such as halogenation, Sonogashira coupling, Knoevenagel condensation, Grignard reagents, Vilsmeir-Haack, and Steglich esterification. Some of these reactions were successful, but the overall synthesis to the targeted final molecule couldn’t be accomplished. Even though further studies on the synthesis of oxide-binding azaBODIPYs are needed, at least my thesis research suggests what reactions can be implemented to complete this synthesis in the future. Proton NMR (nuclear magnetic resonance) and carbon NMR were commonly used to confirm the synthesized compounds, and sometimes crystallographic information was obtained by XRD (X-ray diffraction) whenever crystals of sufficient size and quality were grown. NMR spectra, interpreted by SpinWorks 3 software, and crystal structures will be introduced in each chapter.

photogalvanic dye-sensitized solar cells

azadipyrromethene dyes

synthesis of anchoring group

Metal oxide semiconductors.

Semiconductors -- Bonding.

Dye-sensitized solar cells.

Carboxylic acids.

Characterization of Electrical Properties of Thin-Film Solar Cells

Awni, Rasha A.

January 2020

No description available.

Physics

Energy

Materials Science

capacitance spectroscopy

admittance spectroscopy

impedance spectroscopy

capacitance voltage measurements

current voltage measurements

low temperature measurements

CdTe solar cells

perovskite solar cells

Deposition and Characterization of Solution-Processed Chalcogenides for Photovoltaic Applications

David J Rokke (12468882)

27 April 2022

<p> </p> <p>Combating climate change requires society to shift to using clean, renewable sources of energy as quickly as possible. Photovoltaics (PVs) are a promising source of renewable energy due to the broad availability of solar radiation over the Earth’s surface and the low cost of PV modules. While silicon solar cells dominate the current PV market, some drawbacks motivate the search for other solar materials. Silicon’s indirect band gap necessitates using<br> thick (>100 μm) absorber layers which limits applications to rigid substrates, and manufacturing silicon wafers suitable for solar cell applications requires slow batch processes,<br> hindering the rapid deployment of PV technology.</p> <p><br> One opportunity for realizing rapid manufacturing of PV modules is solution processing, wherein a solar cell is deposited with the use of liquid solutions containing the necessary constituent elements. A solution processing approach could be done in a roll-to-roll format in which a flexible substrate is coated at high speed to create a thin, flexible PV device. Such an approach is expected to dramatically increase the throughput capability of a photovoltaic manufacturing line. To realize the benefits of solution processing, suitable liquid-phase chemistries must be developed to enable the deposition of the desired absorber material while minimizing the incorporation of undesirable contaminants. One such approach is the<br> amine-thiol solvent system which is notable for its ability to solubilize not only metal salts, but also metal sulfides, metal selenides, and pure metals. This makes the amine-thiol system a promising candidate for the deposition of metal chalcogenide absorber layer materials.</p> <p><br> In this work, the chemistry of the amine-thiol system is studied in detail and reaction mechanisms governing the interaction of amine-thiol solutions with precursors relevant to the Cu(In,Ga)(S,Se)2 material system are investigated. Nuclear Magnetic Resonance, Mass Spectrometry, and X-Ray Absorption measurements are performed to study this system. Structures for the metal thiolate species that form in these reactions are proposed, along with the products of the pyrolysis reaction that converts the thiolate species to the desired metal sulfides. The utility of this understanding is discussed.</p> <p><br> The amine-thiol system is further applied to the synthesis of AgIn(S,Se)2, a material with some similarities to the more common metal chalcogenide CuInSe2 but studied far less<br> thoroughly. The material and optoelectronic properties of AgIn(S,Se)2 are characterized. X-Ray Diffraction, Hall Effect Measurements, Kelvin Probe Force Miscropscopy, and Quantitative Photoluminescence are all performed on AgIn(S,Se)2 thin films. AgIn(S,Se)2 films are found to exhibit high carrier mobility, benign grain boundaries, and strong photoluminescence emission, suggesting that AgIn(S,Se)2 may function as an effective absorber layer<br> material for thin-film solar cells. Challenges facing its successful adoption as a solar cell material as discussed.<br> </p> <p>In this work, a novel method is developed to calibrate photoluminescence spectrometers for absolute photon counts, enabling one to calculate the absolute number of photons leaving a photoluminescence sample. This enables an estimation of the Quasi-Fermi Level Splitting of an absorber layer (and hence open-circuit voltage of a solar cell) while only measuring a bare absorber layer film. The experimental method and required numerical analysis of the<br> data are described herein.</p>

Compound Semiconductors

Solar Cells

Photoluminescence

Solution Processing

Chalcogenides