Semi-conducteurs organiques de type n pour la conversion d'énergie / N-type organic semiconductors for energy conversion

Bardagot, Olivier

15 October 2019

A l’heure où les impacts du changement climatique sont devenus indéniables, le développement des énergies décarbonées s’impose. Potentiellement bas coût comparées aux technologies établies, les technologies organiques émergentes offrent une alternative éco-efficiente pour l’exploitation de l’énergie solaire et de l’énergie thermique (< 473 K). Dans le premier chapitre, les avantages et inconvénients des différentes technologies actuellement développées sont discutés. Les dispositifs photovoltaïques, tout comme thermoélectriques, requièrent deux types de matériaux conduisant respectivement les trous (type p) et les électrons (type n). Malgré des avancées remarquables, le développement de semi-conducteurs de type n constitue un levier d’amélioration majeur pour les technologies organiques. Dans ce contexte, ce travail doctoral présente la conception, la synthèse, la caractérisation et la mise en œuvre au sein de dispositifs, de polymères et petites molécules pi-conjugués de type n.Basées sur trois unités électro acceptrices – l’isoindigo (ISI), le naphtalène diimide (NDI) et le benzodifurandione-oligo(p-phénylènevinylène) fluoré (FBDOPV) – la conception et la synthèse de copolymères alternés sont présentées dans le deuxième chapitre. Ces polymères démontrent de hautes affinités électroniques comprises entre 3,5 eV et 4,1 eV. Les études de modélisations DFT et de diffraction de rayons X en couches minces ont permis d’identifier les principaux facteurs structuraux à l’origine des hautes mobilités en électron obtenues en transistor organique à effet de champ allant jusqu’à 0,26 cm2.V-1.s-1.Pour une application thermoélectrique, le dopage moléculaire de ces semi conducteurs organiques est requis et fait l’objet du troisième chapitre. Les conditions nécessaires à la thermo- et photo activation du dopant N-DMBI ont été identifiées. En particulier, la dégradation du dopant activé en présence d’oxygène a été mise en évidence par diffraction de rayons X sur monocristaux. Les polymères et deux petites molécules à base d’ISI et NDI ont été dopés avec succès. Les mécanismes de dopage et les conductivités obtenues sont discutés au cas par cas à l’aide d’expériences spectroscopiques UV Visible-Proche-Infrarouge et Résonance Paramagnétique Electronique. Des conductivités de l’ordre de 10-4 S.cm-1 sont obtenues sans apport énergétique ni avant ni après dépôt. Des conductivités encourageantes de l’ordre de 10-3 S.cm-1 pour une petit molécule à base de NDI et de 10-2 S.cm-1 pour un polymère à base de FBDOPV ont été atteintes. La stabilité et la réversibilité des conductivités des couches minces exposées à l’air ont été examinées et corrélées au niveau LUMO des matériaux. Le contrôle minutieux des conditions de dépôts et de dopage ont permis l’obtention d’un facteur de puissance de l’ordre de 0,3 µW.m 1.K-2 associé à une conductivité thermique de 0,53 W.m-1.K-1. Des figures de mérite d’environ 2.10-4 à 303 K et 5.10-4 à 388 K ont été mesurées, lesquelles représentent les premières valeurs reportées à ce jour pour un semi-conducteur organique dopé n sur un même dispositif.Ces matériaux permettent également le remplacement des dérivés fullerènes en dispositif photovoltaïque comme présenté dans le dernier chapitre. Ils démontrent notamment de forte propriétés d’absorption, étendue jusqu’au domaine proche infrarouge pour l’un des polymères. Un rendement de conversion de 1,3% a été obtenu en cellule solaire à hétérojonction en volume « tout-polymère » avant optimisation. Suivant une conception moléculaire de type donneur-espaceur-accepteur, deux dérivés d’ITIC ont été conçus et caractérisées. La modification de substituants alkyles sur l’espaceur permet d’obtenir des propriétés d’absorptions et d’organisations améliorées comparé à ITIC. De hautes tensions de circuit-ouvert allant jusqu’à 1,10 V et des rendements de 4,2% ont été obtenus avec ces accepteurs non-fullerènes. / At a time when the impacts of climate change have become undeniable, the development of low-carbon energies is crucial. Potentially low cost compared to established technologies, emerging organic technologies offer an eco-efficient alternative for harvesting solar and thermal (< 473 K) energies. In the first chapter, the advantages and drawbacks of the different technologies currently being developed are discussed. Photovoltaic devices, like thermoelectric devices, require two types of materials conducting holes (p type) and electrons (n-type) respectively. Despite remarkable advances, the development of n-type semiconductors represents a major lever for improving organic technologies. In this context, this doctoral work presents the design, synthesis, characterization and device developments of innovative pi-conjugated n-type polymers and small molecules.Based on three electron-accepting units – isoindigo (ISI), naphthalene diimide (NDI) and fluorinated benzodifurandione-oligo(p-phenylenevinylene) (FBDOPV) – the design and synthesis of alternated copolymers are presented in the second chapter. These polymers exhibit high electron affinities ranging from 3.5 eV to 4.1 eV. DFT modelling and thin-film X-ray diffraction studies allowed to identify the main structural aspects leading to electron mobility as high as 0.26 cm2.V 1.s 1 achieved in organic field effect transistors.For thermoelectricity, molecular doping of these organic semiconductors is required. It is the subject of the third chapter. The necessary conditions for thermo- and photo-activation of N DMBI dopant have been identified. In particular, the degradation of the activated dopant in the presence of oxygen has been demonstrated by single crystal X-ray diffraction. Each polymer and two small molecules based on ISI and NDI cores have successfully being doped. The doping mechanisms and conductivities obtained are discussed on a case by case basis using UV-Visible-Near-Infrared and Electron Paramagnetic Resonance spectroscopies. In particular, conductivities in the range of 10-4 S.cm-1 were obtained without external energy supply neither before nor after deposition. Encouraging conductivities in the range of 10-3 S.cm 1 for a small molecule based on NDI and 10-2 S.cm 1 for a polymer based on FBDOPV have been achieved. The stability and reversibility of thin film conductivities when exposed to air were investigated and correlated to the LUMO level of the materials. The thorough control of deposition and doping conditions have afforded to achieve a power factor of about 0.3 µW.m-1.K-2 associated to a thermal conductivity of 0.53 W.m 1.K 1. Figure of merits of approximately 2.10-4 at 303 K and 5.10-4 at 388 K have been obtained, which represent the first values reported to date for an n-doped organic semiconductor measured on a single device.These materials also allow the replacement of fullerene derivatives in photovoltaic devices as presented in the last chapter. In particular, they demonstrate strong absorption properties, extended to the near infrared domain for one of the polymers. A conversion efficiency of 1.3% was obtained in all polymer bulk-heterojunction solar cell before optimization. Following the donor-spacer-acceptor approach, two ITIC derivatives have been designed and characterized. The modification of alkyl substituents on the spacer provides improved absorption and molecular packing properties compared to ITIC. High open-circuit voltages up to 1.10 V and conversion efficiencies of 4.2% have been achieved with these non-fullerene acceptors.

Type n

Dopage moléculaire

Accepteur non-Fullerène

Photovoltaïque organique

Organic semiconductor

N-Type

Molecular doping

Thermoelectricity

Non-Fullerene acceptor

Organic photovoltaics

540

Combined MD/DFT protocol for the simulation of molecular materials for organic solar cells

Turelli, Michele

05 March 2021

In much of the literature about organic photovoltaics, the topic is framed within the current landscape of energy production and the research on these materials is cited as a possible solution to the energy crisis looming ahead. Despite being the most frequent, this is by no means the only perspective that can be offered. Indeed, the same research may also be set within the larger perspective offered by the field of functional materials. These materials are usually exploited for their particular responses to electrical, magnetic and chemical stimuli and are at the basis of many technologies fundamental to our society. The prominent position of functional materials in modern science is due to the emergence of novel technological needs that such materials have been able to satisfy thanks to their peculiar properties. These properties have been rationalised and mastered by expanding the theoretical description of the underlying physical mechanisms. This theoretical body, combined with the growth and diffusion of computational capabilities has fostered a change in the scientific paradigm underpinning the research effort. More and more, the predictive power of numerical approaches is exploited to lead the way in the exploration of the immense chemical space. The ultimate promise is to achieve the purpose-driven design of compounds thanks to which the molecular structure can be engineered before the actual synthesis to meet the demands dictated by a specific application. To fulfil this role, computational approaches need to be able to simulate the solid state properties at the most relevant time and length scales. If this can be accomplished then a reliable prediction of the performance can be achieved. The current work deals with the development and application of one such protocol, for the particular case of organic photovoltaic semiconductors. Given the specific application, the properties targeted are light absorption and charge transport. Particular effort is put in the simulation of local morphologies at scales above the molecular one to describe supramolecular organisation with sufficient resolution. In this thesis, the protocol is applied to two molecular systems employed in solar devices. Both systems have been selected on the basis of data suggesting that a detailed microscopic description of their behaviour could be highly informative about the aspects responsible for their photovoltaic performance. In particular, chapter 3 details the investigation of a small-molecule donor that has been shown in the literature to have a remarkable behaviour in absorption. While chapter 4 reports the study of a donor-acceptor dyad used as active layer in single-component solar devices with relatively high conversion efficiency. In both cases, the computational protocol has proven capable of providing a detailed microscopic description of the systems. The picture drawn has allowed to clarify the plausible mechanisms behind the observations and to rationalise these behaviours in a broader and more general theoretical framework.

Settore CHIM/02 - Chimica Fisica

Etude par microscopie à force atomique en mode non contact et microscopie à sonde de Kelvin, de matériaux modèles pour le photovoltaïque organique / Noncontact Atomic Force Microscopy and Kelvin Probe Force Microscopy investigations of model materials for organic photovoltaics

Spadafora, Evan

04 November 2011

La nanostructure et les propriétés électroniques de matériaux modèles pour le photovoltaïque organique, ont été étudiées en utilisant la Microscopie à Force Atomique en mode non contact sous ultra-vide (NC-AFM) et la Microscopie à sonde de Kelvin (KPFM). En utilisant le mode modulation d'amplitude (AM-KPFM), le potentiel de surface photo- généré dans des mélanges donneur-accepteur présentant une ségrégation de phase optimale a pu être visualisé à l'échelle du nanomètre. Afin de préciser la nature des forces mises en jeu dans le processus d'imagerie KPFM, des oligomères π-conjugués auto-assemblés ont ensuite été étudiés. Une transition entre régimes à longue et à courte portée a ainsi été mise en évidence en combinant l'imagerie en haute résolution aux mesures de spectroscopie en distance. Ces mesures ont également démontré que l'influence des forces électrostatiques à courte portée peut être minimisée en travaillant au seuil du contraste de dissipation. Enfin cette procédure a été utilisée, en combinaison avec les mesures de spectroscopie de photoélectrons UV, pour analyser la fonction de sortie locale d'électrodes transparentes à base de nanotubes de carbone fonctionnalisés. / In this thesis, noncontact atomic force microscopy (NC-AFM) and Kelvin probe force microscopy (KPFM) under ultrahigh vacuum have been applied to investigate the nanostructure and electronic surface properties of model materials for organic photovoltaics. First, it has been demonstrated that the surface photovoltage of nanoscale phase segregated donor-acceptor photovoltaic blends can be finely resolved at the nanometer scale by using amplitude modulation KPFM (AM-KPFM). Next, model self-assembled π-conjugated oligomers have been investigated, in order to obtain a deeper insight into the nature of the tip-surface forces involved in the KPFM imaging process. A crossover between long-range (LR) and short-range (SR) regimes has been evidenced by combining high resolution imaging with distance-spectroscopy measurements. It has also been shown that the influence of the SR electrostatic forces can be minimized by working at the onset of the damping contrast. Finally, using this procedure, the local work function of flexible transparent electrodes, comprised of functionalized carbon nanotubes by metallic nanoparticles, has been investigated, and compared to the averaged value deduced from ultraviolet photoelectron spectroscopy.

AFM non contact

,photovoltaïque organique

Auto-assemblages moléculaires

Microscopie à sonde de Kelvin

NC-AFM

Organic photovoltaics

MOLECULAR SELF-ASSEMBLIES

Kelvin Probe Force Microscopy

530

Modélisation multi-échelle de polymères conjugués pour le photovoltaïque organique : confrontation expérience / théorie / Multiscale modelling of conjugated polymers for organic photovoltaic : experiment / theory confrontation

Arnaud, Marc-Alexandre Dimitri

11 September 2013

Ce travail de recherche prédictive, couplé à des synthèses expérimentales, a pour but d'anticiper la bonne adéquation entre un nouveau polymère donneur de type P3HT et un composé accepteur innovant à base de graphène. Cette étude a notamment porté sur i) la bande d'absorption du polymère donneur « low band gap », ii) sa robustesse face à la dégradation (cristallinité, résistance à l'oxydation), iii) la modulation des propriétés électroniques d'un dérivé de graphène (accepteur) en adéquation avec le donneur. Les résultats montrent que les polythiophènes ayant un substituant éther OR permettent l'amélioration de la conjugaison, de la rigidité, de la cristallinité et de la photostabilité tout en étant électroniquement compatible avec l'hexabenzocoronène fonctionnalisé (acide caorboxylique). De plus, ce nouvel accepteur sera pleinement compatible avec une électrode de graphite grâce à sa prédisposition à l'empilement colonnaire. / This predictive research work, combined with an experimental study, aims at anticipate the behavior of a new donor :acceptor pair constituted by a P3HT-type of polymer and an innovative graphene-based acceptor material (HBC). This study is particularly interested in i) the absorption band of the donor (a « low band gap » polymer) and ii) its resistance towards degradation (cristallinity, oxidation stability), and finally iii) the modulation of the electronic properties of the acceptor, in keeping with those of the donor. Results show that polythiophenes grafted with an –OR group improve both conjugation, rigidity, cristallinity and photostability, in addition to their great electronic compatibility with functionalized HBCs. Besides, this new acceptor material will be fully compatible with a graphite electrode, thanks to its columnar structuration.

Photovoltaïque organique

Polymère « low band gap »

Modélisation quantique

Stabilité photochimique

Hexabenzocoronène.

Organic photovoltaics

« low band gap » polymer

Quantum modelling

Photochemical stability

Hexabenzocoronene

Ultrafast spectroscopy of organic semiconductors : singlet fission and nonfullerene acceptors for organic photovoltaics

Kim, Vincent Oteyi

January 2019

In this dissertation, we investigate two emerging strategies for enhancing the performance of organic photovoltaics. The first takes advantage of a process called singlet exciton fission, and the second embodies an exodus from the fullerene electron acceptors prominent in organic solar cells. Indeed, this versatile class of tunable small molecules are aptly termed nonfullerene acceptors. However, both strategies would benefit from a greater understanding of underlying principles. Singlet exciton fission is a photon-multiplying process in which a singlet exciton from a high-energy absorbed photon splits into two triplet excitons. The process could significantly reduce energy lost to heat in photovoltaic devices, but its mechanisms are still misunderstood. One model involves direct coupling between the singlet and triplet states, and another model involves an intermediate charge transfer state. Transient absorption spectroscopy allowed us to examine singlet fission in films of pentacene, fluorinated pentacene, and coevaporated blends of various mixing ratios. We directly observe an intermolecular charge transfer state during singlet fission in solid films of coevaporated pentacene and peruoropentacene, which supports the model of charge transfer state-mediated singlet fission. Furthermore, we successfully induced singlet fission in one blend by directly exciting the charge transfer state below the bandgap. We use various types of steady state and time-resolved spectroscopy to characterize two types of nonfullerene electron acceptors. The first type is a group of tetraazabenzodiuoranthene diimide (BFI) dimers and a BFI monomer. The BFI dimers were designed to have twisted, nonplanar 3-dimensional structures and have helped achieve power conversion efficiencies of over 8% in organic solar cells. The other type of nonfullerene acceptor is a calamitic small molecule, and we consider the BAF-4CN electron acceptor, which has also been used in a solar cell whose efficiency exceeded 8%. Spectroscopic studies give insight into the performances of these nonfullerene devices in relation to fullerene-derivative counterparts. We find that the nonfullerene blends suffer from more geminate charge recombination. However, despite this drawback, in some cases, slower rates of nongeminate recombination may lead to successful power conversion efficiencies in nonfullerene solar cells.

Morpological Architecturing of Electroactive Materials in Organic Electronics

Khanum, Khadija Kanwal

January 2015

Morphological architecturing is one of the smart and efficient ways to maximize the number of excitons harvested from the known photoactive materials and existing fabrication technologies. Surfaces and interfaces play a vital role in absorbing light and therefore when patterned regularly, aid in the improvement of light absorption. This thesis deals with the study of light management by morphologically architecturing the organic electroactive materials. Here, morphological architecturing is carried out using electrospinning technique by optimizing various parameters. In the first part, organic photovoltaic system is tailored by morphologically modifying the conjugated polymer active layer and analyzing the enhancement in light collection and hence performance of photovoltaic devices. In the second part, the prospects of using free standing buffer layer instead of thin film buffer layer in a solar cell is evaluated. Furthermore, the study on morphological engineering of conjugated small molecule is carried out, by varying the solvents and derivatives, in order to control morphologies by understanding the underlying mechanism. Overall this thesis attempts to understand the fundamentals in morphological architecturing, by physical architecturing of the small molecules in a device for light management applications as well as demonstrating improvement in light absorption in existing organic photovoltaic systems. In the introduction chapter, a brief description of organic photovoltaics is given followed by highlighting the importance of processing methods in light management and in organic photovoltaics. The significance of structured architecture in improving the device characteristics is presented. The issues and challenges in existing architecturing techniques available in literature are discussed. Electrospinning as a tool for morphological modification for organic photovoltaics is demonstrated. This is followed by an outline of the thesis. In Chapter 2, brief description of procedures carried out for fabrication, characterization and optimization of electrospinning process parameters are discussed. The description of fabrication procedures including electrospinning, spincoating and thermal evaporation are given. Characterization techniques used in this thesis for surface and feature analysis, structural, compositional, optical and opto-electrical analyses are described. Optimization of electrospinning process parameters in obtaining various morphologies are evaluated. In Chapter 3, enhancement of device characteristics of poly (3-hexylthiophene): phenyl C61-butyric acid methyl ester (P3HT: PCBM) by changing active layer film morphology into network structure is elucidated. Network structure is provided by electrospraying assisted hierarchical assembly of short fibrils. Effect of electrospraying parameters such as solvent, polymer blend concentration, applied voltage, tip to collector distance, flow rate and deposition time are analyzed. Solvent and applied voltage are observed to be the major parameters governing the formation of network structure. The optimized conditions are used to investigate the optical and structural properties. Percent reflectance studies showed improvement in light absorption due to increase in surface area. Structural characterization studies indicate an increase in orientation of crystallites and crystallinity as compared to spincoated samples. The optimized conditions along with additional spincoated layer of P3HT:PCBM are used to fabricate bulk heterojunction device. Device characteristics exhibited an increase in short circuit current and thus increase in efficiency from 2.18% to 3.66%. There is a enhancement of 37.5% going from maximum external quantum efficiency of 40%-55% for electrosprayed and spincoated devices. It is anticipated that network morphology could be the next possible structure to be explored in organic photovoltaic materials. In Chapter 4, photonic structure is analyzed and compared. A photonics device requires uniform periodic structural arrangement. Various techniques are used to fabricate these types of structures, employing several steps of fabrication. This work proposes single step hierarchical array of equal submicron size porous structure fabricated by tuning electrospinning processing parameters. The dictating process parameters on evolving structure are high voltage, tip to collector distance and solvent. Morphological and optical investigations suggest that uniform periodic topography helps in light scattering leading to multi reflection and thus enhancement in light absorption. This structure is evaluated as active layer in organic photovoltaic devices using poly (3 hexyl thiophene) (P3HT) and phenyl-C61-butyric acid methyl ester (PCBM) blend and its device characteristics are analyzed. Consistent and reliable device characteristics obtained through photonic structure is demonstrated. Finally, comparison is drawn to network structure to assess the advantages and limitations of both morphologies as active layer in organic photovoltaics. In Chapter 5, instead of architecturing active layer the next polymer film layer in the organic solar cells, that is the hole transport layer is transformed into free standing nanofiber mats. Morphological, structural and surface wetting properties are assessed for these nanofiber mats followed by fabrication of inverted organic solar cell. The free standing nanofibers mats are obtained by electrospinning the blend of Poly(3,4-ethylenedioxythiophene) Polystyrene sulfonate (PEDOT:PSS) a conducting water soluble polymer with other water soluble polymers such as poly vinyl alcohol (PVA) and poly ethylene oxide (PEO). The study is further extended by employing two batches of PEDOT:PSS of varying conductivity that are analyzed side by side for six ternary and two binary blends each. Electrospinning parameters such as applied voltage and flow rate are optimized and fibers of diameter 150-200 nm are obtained. Maximum content of PEDOT:PSS with which free standing fiber mats could be achieved are 98 and 99%. Subsequent increase in PEDOT:PSS results in formation of beads. Surface wetting behavior showed that hydrophillicity increases with increase in PEDOT:PSS content. Devices are fabricated and the variation in characteristics and charge collection with respect to addition of PEO and PVA are discussed. In Chapter 6, a conjugated small molecule is taken as case study unlike the use of the conjugated polymer studies in previous chapters. A mechanism is proposed for tuning the sphere-spike morphology and also to control the crystallite size through solvent management using a conjugated small molecule. Electrospraying of an organic molecule is carried out using various solvents, obtaining fibril structures along with a range of distinct morphologies. Solvent characteristics play a major role in achieving the morphology of the organic material. A thiophene derivative (7, 9-di (thiophen-2-yl)-8H-cyclopenta [a]acenaphthylen-8-one) (DTCPA) of donor-acceptor-donor (DAD) architecture is used to study this solvent effect. Seven solvents with decreasing vapor pressure are selected for experiments. Electrospraying is conducted at a solution concentration of 1.5 wt % and a constant applied voltage of 15 kV. Gradual transformation in morphology of the electrospun product from spikes-sphere to only spikes is observed. A mechanism describing this transformation is proposed based on the electron micrograph analysis and XRD analysis. These data indicate that the morphological change is due to the synergistic effect of both vapor pressure and dielectric constant of the solvents. Through a reasonable control over the crystallites size and morphology along with supporting transformation mechanism theory, the work in this chapter elucidates electrospraying as a prospective method for designing the architectures in organic electronics. In Chapter 7, light management studies are carried out by morphologically architecturing the carbazole derivatives through electrospraying. The effect of derivatives on morphology is analyzed. The two carbazole derivatives; carbazole-benzothiadiazole (Cz-Bz) resulted in 2D structures and carbazole-benzothiadiazole-bithiophene (Cz-Bz-Bt) resulted in 3D structures after electrospraying. These structures are further analyzed to study the effect of vapor pressure of solvents and solution concentration. Structural characteristics indicate that electrospraying imparts change in molecular structure orientation. Optical studies showed 19 – 31% enhancement in light absorption. Further, three types of organic photovoltaic devices are fabricated and the opto-electrical properties are evaluated. Also, the effect of substrate on morphological formation is assessed. In Chapter 8, the major contributions and conclusions drawn from the morphological architecturing of both conjugated polymers and small molecules are summarized, along with few recommendations for future research.

Materials Engineering

Electroactive Materials

Electrospinning

Organic Photovoltaics

Organic Electronics

Morphological Architecturing

Organic Electroactive Materials

Organic Solar Cells

Thiophene Derivative

PEDOT

Electrosprayed Photoactive Materials

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

Ternary blend ink formulations for fabricating organic solar cells via inkjet printing / Formulations ternaires d'encre de mélange pour fabriquer les piles solaires organiques par l'intermédiaire de l'impression de jet d'encre

Kraft, Thomas

27 May 2015

L’objectif final de la thèse est l'impression de la couche photo-active ternaire d'une cellule solaire organique en utilisant deux approches: l'une concerne l'apport de nanotubes de carbone (SWCNT) pour améliorer les propriétés de transport, l'autre concerne la préparation de mélanges ternaires de matériaux pour contrôler la couleur des cellules. Les encres pour la couche active incluant des SWCNT fonctionnalisés sont composées d’un donneur d'électron (polymère) (poly(3-hexylthiophène), [P3HT]) et d’un accepteur d'électron ( [6,6]-phényl C61-butyrique ester méthylique d'acide [PCBM]) et ont été développées pour la fabrication de cellules inversées. Ces cellules sont réalisées sur substrats de verre pour l'optimisation de leurs performances, puis sur substrats plastiques pour les applications. Diverses couches d'interfaces ont été testées, qui incluent l'oxyde de zinc (ZnO, couches obtenues par pulvérisation ionique (IBS) ou à partir de solutions de nanoparticules) pour la couche de transport d'électrons et le PEDOT:PSS, le P3MEET, le V2O5 et le MoO3 pour la couche de transport de trous. Des essais ont été effectués avec et sans CNT afin d’étudier leur impact sur les performances. Des résultats similaires sont obtenus dans les deux cas. Il était attendu que les CNT améliorent les performances, ce qui n’a pas été observé pour le moment. Des travaux supplémentaires sont donc nécessaires au niveau de la formulation de la couche active.Avec trois polymères de couleur rouge (P3HT), bleu (B1) et vert (G1), nous avons préparé des mélanges ternaires efficaces permettant l'obtention de couleurs jusque là indisponibles . Nous avons fait une étude sur le piégeage et les mécanismes de diodes parallèles associés aux mélanges. En général, nous avons constaté que les mélanges ternaires de polymères bleu et vert peuvent être décrits par une mécanisme de diodes parallèles, sans entrainer de perte de performances, ce qui n'est pas possible pour les systèmes P3HT:B1 :PCBM et P3HT:G1:PCBM qui se piègent mutuellement. L’objectif final du projet est l'impression de la couche photo-active ternaire d'une cellule solaire organique, composites ternaires (polymère:polymères:acceptor) ou dopés avec les SWCNT. Cette étape nécessite encore des développements futurs. / Two approaches were followed to achieve increased control over properties of the photo-active layer (PAL) in solution processed polymer solar cells. This was accomplished by either (1) the addition of functionalized single-walled carbon nanotubes (SWCNTs) to improve the charge transport properties of the device or (2) the realization of dual donor polymer ternary blends to achieve colour-tuned devices.In the first component of the study, P3HT:PC61BM blends were doped with SWCNTs with the ambition to improve the morphology and charge transport within the PAL. The SWCNTs were functionalized with alkyl chains to increase their dispersive properties in solution, increase their interaction with the P3HT polymer matrix, and to disrupt the metallic characteristic of the tubes, which ensures that the incorporated SWCNTs are primarily semi-conducting. P3HT:PCBM:CNT composite films were characterized and prepared for use as the photoactive layer within the inverted solar cell. The CNT doping acts to increase order within the active layer and improve the active layer’s charge transport properties (conductivity) as well as showed some promise to increase the stability of the device. The goal is that improved charge transport will allow high level PSC performance as the active layer thickness and area is increased, which is an important consideration for large-area inkjet printing. The use of ternary blends (two donor polymers with a fullerene acceptor) in bulk-heterojunction (BHJ) photovoltaic devices was investigated as a future means to colour-tune ink-jet printed PSCs. The study involved the blending of two of the three chosen donor polymers [red (P3HT), blue (B1), and green (G1)] with PC61BM. Through EQE measurements, it was shown that even devices with blends exhibiting poor efficiencies, caused by traps, both polymers contributed to the PV effect. However, traps were avoided to create a parallel-like BHJ when two polymers were chosen with suitable physical compatibility (harmonious solid state mixing), and appropriate HOMO-HOMO energy band alignment. The parallel diode model was used to describe the PV circuit of devices with the B1:G1:PC61BM ternary blend.

Cellule solaire organique

Couche photo-active ternaire

SWCNT

Cellule solaire polymères

PBHJ

Organic photovoltaics

Ternary blend BHJ

SWCNT

Polymer solar cells

Parallel BHJ

621.47

Matériaux « uniques » pour cellules solaires organiques mono-composant / « Unique » materials for single-component organic solar cells

Labrunie, Antoine

18 December 2017

Au cours des dernières années, le développement des cellules organiques à réseaux interpénétrés a permis d’améliorer les rendements de conversion photovoltaïque (PV). Ces dispositifs incorporent une couche active constituée d’un mélange d’un matériau donneur d’électron (D) et d’un matériau accepteur d’électron (A). La réalisation de ces cellules requiert une optimisation minutieuse de ce mélange et de la morphologie de cette couche photo-active qui en résulte. Cette dernière peut cependant évoluer spontanément vers une ségrégation de phase, généralement délétère pour les performances PV. Une solution possible, et relativement peu étudiée, consiste à lier chimiquement le donneur D et l’accepteur A par un espaceur non-conjugué. Les travaux décrits dans ce manuscrit portent sur la synthèse et la caractérisation d’assemblages moléculaires de type D-σ-A ainsi que leur utilisation comme matériau dit « unique » pour la fabrication de cellules solaires organiques mono composant. Une première famille de dyades et triades à base d’un bloc donneur de type quaterthiophène a été étudiée. Cette partie décrit la méthodologie générale d’assemblage des blocs D et A via une réaction de cycloaddition de type Huisgen. Au cours des chapitres suivant, plusieurs dyades basées sur un bloc donneur « push-pull » ont été synthétisées puis caractérisées. Les performances PV de ces composés ont été évaluées au sein de cellules solaires mono-composant et les meilleurs rendements de conversion, atteignant 1.4 %, rivalisent avec l’état de l’art. / Over the last few years, the development of bulk heterojunction organic solar cells (BHJ OSCs) led to significant increase in photovoltaic (PV) efficiency. Such devices are based on interpenetrated networks of an electron-donor material (D) and an electron-acceptor material (A) constituting the active layer. Nevertheless a careful optimization of the morphology is required to reach high power conversion efficiency. Furthermore, this optimized morphology can evolve towards spontaneous phase segregation which can be detrimental for the PV performances. To circumvent these limitations, a relatively unexplored approach relies on the use of a material where the donor and the acceptor moieties are covalently linked to each other through a nonconjugated π-connector. In this context, the work reported herein describes the synthesis and characterization of various molecular D-σ-A assemblies, as well as their preliminary evaluation as “unique” material for the realisation of single component organic solar cells (SC-OSCs). A first family of dyads and triads, based on quaterthiophene moieties as donor block, was studied. A general methodology to assemble the two D and A blocks via a Huisgen-type click-chemistry is described. Then, in the next chapters, several dyads based on a “push-pull” donor block have been synthesized and characterized. The PV performances of these compounds have been evaluated in SC-OSCs leading to power conversion efficiency up to 1.4 %, a value close to the state of the art.

Photovoltaïque organique

Synthèse organique

Cellules solaires mono-Composant

Oligothiophène

Push-Pull

Multimères

Organic photovoltaics

Organic synthesis

Singlematerial solar cells

Click Chemistry

Oligothiophenes

Push-Pull

Fullerenes

Multimers

540

Synthèse et caractérisation de matériaux semi-conducteurs pour la conversion photovoltaïque / Synthesis and characterization of organic semiconductors for voltaic applications

Bulut, Ibrahim

03 June 2015

L’objectif de cette thèse consiste à développer des matériaux semi-conducteurs organiques efficaces pour le photovoltaïque organique. Le travail est focalisé sur l’optimisation de matériaux à caractère donneur d’électrons pour la préparation de dispositifs à hétérojonction volumique, en association avec un dérivé de fullerène comme matériau à caractère accepteur d’électrons. Plus particulièrement, il s’agit de réaliser une étude d’optimisation systématique de deux familles de référence (respectivement macromoléculaire et moléculaire) issus du laboratoire, qui ont déjà conduit à des performances photovoltaïques intéressantes. Pour cela, nous avons suivi une démarche rigoureuse et systématique en ciblant les paramètres chimiques les plus pertinents à faire varier. Afin de déterminer les propriétés des nouveaux matériaux ainsi synthétisés, des caractérisations spectroscopiques, électrochimiques, structurales, de transport de charge et photovoltaïque ont systématiquement été effectué. / The aim of this thesis is to develop efficient semi-conducting organic materials for organic photovoltaics. This work is focuses on the optimization of electron-donor organic semiconductors for the preparation of bulk heterojunction devices, in blend with a fullerene derivative used as electron-acceptor material. More specifically, it is to perform a systematic optimization study of two reference families (macromolecular and molecular respectively) from the laboratory, which have already led to interesting photovoltaic performances. For this, we followed a structured and systematic approach targeting the most relevant chemical parameters to be varied. To determine the properties of new materials synthesized, spectroscopic, electrochemical, structural, charge transport and photovoltaic characterizations were systematically made.

Photovoltaïque organique

Semi-conducteurs macromoléculaires

Semi-conducteurs moléculaires

Cellules solaires organiques

Donneur-accepteur

Propriétés optoélectroniques

Organic photovoltaics

Macromolecular semiconductors

Molecular semiconductors

537.6

541.3