Global ETD Search

11	Scanning Tunneling Microscopy Investigation of Interfacial Properties between P3HT and PCBM Shih, Min-Chuan 21 July 2011 (has links) The electronic structures at the hetero interface of Poly(3-hexylthiophene): methanofullerene (P3HT:PCBM) have a great improvement on the solar cell efficiency due to the formation of bicontinuous nanoscaled phase separation which will enhance charge separation and carrier transport. In the present work, cross-sectional scanning tunneling microscopy and scanning tunneling spectroscopy measurements are utilized to obtain the in-situ atomic-scale band structure across the interface between P3HT and PCBM directly. The distribution of PCBM volume concentration of organic films was also analyzed and discussed in the work. scanning tunneling spectroscopy P3HT PCBM interface Scanning tunneling microscopy
12	The Study of Organic Solar Cell Doped with Metallic Nanoparticle Tsai, Ying-Chen 21 July 2008 (has links) Polymers are with low carrier mobility. If polymer solar cells are to exhibit high power conversion efficiencies, their carrier mobilities must be improved. Metallic NPs are promising materials for use in polymer solar cells because of their high conductivities. In this work, we studied the carrier transport characteristic of metallic nanoparticle blending into polymers. We blended Pt nanoparticles (Pt NPs) and Pd nanoparticles (Pd NPs) into polymers to improve carrier mobility, and enhance the power conversion efficiency of the polymer solar cell. P3HT was used as a donor material because of its high stability and with high absorption in visible light. PCBM was used as a acceptor material because of its high stability and with high electron transportation. We blended modified Pt NPs and Pd NPs into the P3HT:PCBM active layer, with the device configurations of ITO/PEDOT:PSS/P3HT:PCBM: Pt NPs/Al and ITO/PEDOT:PSS/P3HT:PCBM:Pd NPs/Al, respectively polymer solar cells measured was under AM 1.5G 100mW/cm2 illumination. When we blended Pt NPs into the active layer, the open-circuit remained 0.64V, the short-circuit current increased from 6.67mA/cm2 to 9mA/cm2, the power conversion efficiency increased from 1.96% to 3.08%. When we blended Pd NPs into the active layer, the open-circuit remained 0.62V, the short-circuit current increased from 6.33mA/cm2 to 7.33mA/cm2, the power conversion efficiency increased from 1.7% to 2.48%. The enhanced efficiency originated from the increased carrier mobility of the active layer when the Pt NPs or Pd NPs were present. P3HT Pd nanoparticles Pt nanoparticles organic solar cell PCBM
13	Graphene-enhanced Polymer Bulk-heterojunction Solar Cells Yu, Fei 10 September 2015 (has links) No description available. Materials Science Graphene Solar cell Bulk-heterojunction P3HT PCBM Morphology
14	Caractérisation, optimisation et comportement photochimique de couches actives de cellules photovoltaïques organiques à base de poly(3-hexylthiophène) / Characterization, optimization and photochemical behavior of active layers of organic photovoltaic cells based on poly(3-hexylthiophene) Dupuis, Aurélie 01 June 2012 (has links) Ce travail a été consacré à la caractérisation, l’optimisation et l’étude du comportement photochimique de couches actives de cellules photovoltaïques organiques. L’objectif était d’identifier les mécanismes de photovieillissement dans le but de proposer des stratégies pour améliorer la stabilité de cellules solaires organiques à base de Poly(3-hexylthiophène) (P3HT) et de [6,6]-phényl-C61-butanoate de méthyl (PCBM). Le premier axe de travail a été consacré à l’étude de l’influence des paramètres structuraux du P3HT (masse molaire, régiorégularité, pureté …) sur sa stabilité photochimique dans un premier temps, puis sur l’optimisation des performances des cellules dans un second temps. Pour ce faire, quatre P3HT commerciaux différents ont été étudiés. Ils ont tout d’abord été caractérisés avec précision grâce à différentes techniques analytiques. La relation entre microstructure du P3HT et sa photostabilité a ensuite été étudiée, et les paramètres pertinents influençant la photodégradation identifiés. Le deuxième axe de travail a été consacré à la stabilité photochimique de mélanges P3HT:PCBM sur substrat inerte, puis sur des couches tampons. Dans une dernière partie, la dégradation de couches actives au sein de dispositifs complets a été effectuée en faisant « l’autopsie » de cellules vieillies. / This work was devoted to optimization, characterization and photochemical behavior of active layers of organic solar cells. The objective was to identify photo-ageing mechanisms in order to propose strategies to improve the stability of Poly (3-hexylthiophene) (P3HT)/[6,6]-phenyl-C61-butanoic acid methyl ester (PCBM) organic solar cells. The first axe of this work was devoted to the study of the influence of structural parameters of P3HT (molecular weight, regioregularity, purity …) firstly on its photochemical stability and secondly on the optimization of the performances of devices. In this goal, four different commercial P3HT were studied. They were first characterized accurately with different analytical techniques. The relationship between P3HT microstructure and photostability has been studied and relevant parameters influencing photodegradation have been identified. The second axe of this work was devoted to the photochemical stability of P3HT:PCBM blends on inert substrate, and then on buffer layers. Finally, the degradation of active layers in complete devices has been performed by making the “autopsy” of degraded solar cells. Couche active Cellules photovoltaïques organiques P3HT PCBM Microstructure Vieillissement Stabilité photochimique Active layer Organic solar cells P3HT PCBM Microstructure Ageing Photochemical stability
15	Modified Equivalent Circuit for Organic Solar Cells January 2015 (has links) abstract: In this work a newly fabricated organic solar cell based on a composite of fullerene derivative [6,6]-phenyl-C61 butyric acid methyl ester (PCBM) and regioregular poly (3-hexylthiophene) (P3HT) with an added interfacial layer of AgOx in between the PEDOT:PSS layer and the ITO layer is investigated. Previous equivalent circuit models are discussed and an equivalent circuit model is proposed for the fabricated device. Incorporation of the AgOx interfacial layer shows an increase in fill factor (by 33%) and power conversion efficiency (by 28%). Moreover proper correlation has been achieved between the experimental and simulated I-V plots. The simulation shows that device characteristics can be explained with accuracy by the proposed model. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2015 Electrical engineering Materials Science Equivalent circuit Fill-factor Interfacial layer Organic solar cells P3HT/PCBM
16	Aggregates of PCBM Molecules: A computational study Kaiser, Alexander, Probst, Michael, Stretz, Holly A., Hagelberg, Frank 15 May 2014 (has links) Small clusters of [6,6] phenyl-C61-butyric acid methyl ester (PCBM) molecules are analyzed with respect to their equilibrium geometries and associated electronic as well as energetic properties. Plane wave density functional theory (PWDFT) computations, assisted by molecular dynamics (MD) simulations, are performed on systems of the form PCBMn (n = 1-5). The bonding operative in these units is described as a cooperation between HO bonding, involving the C5H9O2 groups of the PCBM molecule, and fullerene-fullerene attraction. The maximally stable structures identified tend to include a dimer motif that combines both interaction modes. The great importance of van-der-Waals effects in stabilizing the studied clusters is demonstrated by comparing the PCBM3 series with and without inclusion of a van-der-Waals term in the PWDFT procedure. The two approaches yield reverse orders of stability. A decreasing tendency in the Kohn-Sham HOMO-LUMO gaps of PCBMn with the cluster size may be used to monitor PCBM aggregation in the active layer of organic photovoltaic devices by optical spectroscopy. organic photovoltaics PCBM plane-wave density functional theory solar conversion van-der-Waals interaction Physics and Astronomy
17	Organic Solar Cell Fabrication and Study on the Influence of Spin-dependent Processes on the Photocurrent using Spin-sensitive Techniques Olsmats Baumeister, Ronja, Roxner, Evelina January 2022 (has links) Research in recent years on novel materials in organic solar cells (OSCs) have contributed to a rapid advancement in OSC efficiency. Here, OSCs with the well-studied organic semiconductors poly(3-hexylthiophene):[6,6]-phenyl C60-butyric acid methylester (P3HT:PCBM) in a bulk heterojunction structure were prepared to establish a baseline procedure for fabrication and spin-sensitive spectroscopy. Spin-sensitive spectroscopy can be used to probe the spin-dependent processes and loss mechanism in OSCs. Understanding the microscopic processes enables research targeting loss mechanisms directly, which opens up for higher efficiency OSCs. Measurements with continuous wave electrically detected magnetic resonance (cwEDMR), continuous wave electron paramagnetic resonance (cwEPR) and transient (tr)EDMR were set up and followed by an initial study on the spin-dependent processes and their influence on the photocurrent. Signals from spin-dependent processes in the samples were seen for the three experiment series carried out, and well-functioning OSCs with consistent results were prepared. This thesis and the presented baseline fabrication and experimental setup procedures provide with valuable learnings for future research in the group AG Behrends enabling fabrication and spin-sensitive studies on novel materials in OSCs. It was found that post-processing annealing at 120 C for 5 min reduces S-shape behaviour in current-voltage curves, and over all improves poor current-voltage characteristics of the OSC samples fabricated. Further, influence from PEDOT:PSS was seen in cwEPR spectroscopy, indicating the presence of traps or free radicals in the PEDOT:PSS. In cwEDMR spectroscopy of the OSCs it was shown that the spin processes of bias-induced and photo-induced charge carriers influence the photocurrent in the same way. Finally, the authors suggest that results from spin-sensitive spectroscopy of degraded OSCs cannot be applied to non-degraded OSCs. EDMR EPR trEDMR PEDOT:PSS PCBM P3HT organic solar cells osc opv Engineering and Technology Teknik och teknologier
18	Copolymères à blocs « rigide-rigide » pour les cellules photovoltaïques organiques. / Rod-Rod block copolymers for organic photovoltaic cells Medlej, Hussein 07 December 2011 (has links) Les performances des cellules photovoltaïques organiques de type hétérojonction en volume sont entre autres influencées par les propriétés opto-électroniques du polymère semiconducteur donneur d’électrons. L’objectif de cette thèse était de développer de nouveaux polymères π-conjugués pour permettre une meilleure exploitation du spectre solaire et donc améliorer la photogénération des charges. Pour cela, plusieurs dérivés de polythiophènes comportant des substituants aromatiques phényles ont été synthétisés par la méthode de GRIM, à noter l’homopolymère poly[(3-(4-hexylphényl) thiophène] (P3HPT) et le copolymère à blocs poly[3-(4-hexylphényl)thiophène]-bloc-poly(3-hexylthiophène) (P3HPT-b-P3HT). Nous avons également étudié une nouvelle famille de polymères à faible bande interdite basés sur l’alternance d’unités thiophène et dithiéno[3,2-b:2′,3′-d]silole riches en électrons et 2,1,3- benzothiadiazole pauvres en électrons. Après synthèse des différents monomères, les copolymères alternés ont été ensuite obtenus par polycondensation par couplage de Stille. Les différents matériaux synthétisés ont été d’abord caractérisés par analyse thermogravimétrique et par calorimétrie différentielle à balayage afin d’étudier leurs propriétés thermiques. Ensuite, des caractérisations structurales (en particulier DRX et neutrons), optiques (UV-visible) et morphologiques (AFM) ont été réalisées. A partir des résultats obtenus, nous avons pu évaluer les relations entre les structures et les propriétés des matériaux. Finalement, des cellules photovoltaïques à base des polymères synthétisés ont été réalisées et leurs performances ont été corrélées aux propriétés des matériaux. / The performances of organic solar cells based on the concept of bulk heterojunction configuration are strongly influenced by the optoelectronic properties of the electron donor polymer. The aim of this thesis was to develop new π-conjugated polymers to allow a better exploitation of the solar spectrum and thus improving the photogeneration of charges. For this,several polythiophene derivatives substituted by phenyl aromatic groups have been synthesized by the GRIM method, note the homopolymer poly[(3-(4-hexylphenyl)thiophene] (P3HPT) and the diblock copolymer poly[3-(4- exylphenyl)thiophene]-block-poly(3- hexylthiophène) (P3HPT-b-P3HT). We also studied a new family of low band gap polymers based on the alternation of electron-rich thiophene and dithieno[3,2-b:2′,3′-d]silole units andelectron-deficient 2,1,3-benzothiadiazole units. After synthesis of the various monomers, alternating copolymers were then obtained by Stille cross-coupling polycondensation. The different synthesized materials were first characterized by thermogravimetric analysis and by differential scanning calorimetry to study their thermal properties. Then, structural(especially XRD and neutron), optical (UV-visible) and morphological (AFM) characterizations were performed. From the obtained results, we were able to evaluate the relation between structures and properties of materials. Finally, photovoltaic cells based on the synthesized polymers were performed and their performances were correlated to material properties. Photovoltaïque organique Polythiophènes GRIM PCBM Copolymères à blocs Polymères à faible bande interdite Polycondensation par couplage de Stille Copolymères alternés Organic photovoltaic Polythiophenes GRIM PCBM Diblock copolymer Low band polymers Stille cross-coupling polycondensation Alternating copolymers
19	Synthèse de (co)polymères à base de Poly(3-hexylthiophène) pour le photovoltaïque organique Nicolet, Célia 12 December 2011 (has links) L’optimisation de la morphologie de la couche active est primordiale pour l’augmentation des rendements des cellules solaires photovoltaïques organiques. Nous avons montré l’influence du ratio de matériaux donneur (P3HT) et accepteur (PCBM) d’électrons ainsi que de la masse molaire du P3HT sur la morphologie de la couche active. Afin de contrôler la séparation de phases entre les matériaux donneur et accepteur d’électrons, il est possible d’utiliser des copolymères à blocs afin d’aider la compatibilisation entre le P3HT et le PCBM. Nous avons choisi de synthétiser des copolymères à blocs P3HT-b-polystyrène et des P3HT-b-polyisoprène présentant une certaine compatibilité avec les matériaux de la partie active. L’ajout optimisé de P3HT-b-polyisoprène permet une augmentation de 30% des rendements et de 90% de durée de vie des cellules solaires. / Active layer morphology optimization is fundamental to achieve high efficiency in organic photovoltaic solar cells. We showed the influence of the donor (P3HT) and acceptor (PCBM) material ratio and the impact of the P3HT molecular weight on the active layer morphology. We demonstrated the possibility of using well-designed block copolymers to help P3HT and PCBM compatibilization and to control their phase separation. We chose to synthesize P3HT-b-polystyrene and P3HT-b-polyisoprene for which each block is compatible with the active materials. Optimal addition of P3HT-b-polyisoprene enables to get a 30%-improved efficiency and a 90%-enhanced lifetime of the solar cells. Cellule solaire organique P3ht/pcbm Morphologie de la couche active Diagramme de phases Compatibilisant Copolymère à blocs Hétérojonction volumique Performance photovoltaïque Organic solar cell P3ht/pcbm Active layer morphology Phase diagram Compatibilizer Block copolymer Bulk heterojunction Photovoltaic characteristic
20	Thin films of polyfluorene:fullerene blends - Morphology and its role in solar cell performance Björström Svanström, Cecilia January 2007 (has links) <p>The sun provides us daily with large quantities of energy in the form of light. With the world’s increasing demand of electrical energy the prospect of converting this solar light into electricity is highly tempting. In the strive towards mass-production and low cost solar cells, new types of solar cells are being developed, e.g. solar cells completely based on organic molecules and polymers. These materials offer a promising potential of low cost and large scale manufacturing and have the additional advantage that they can be produced on flexible and light weight substrate which opens for new and innovating application areas, e.g. integration with paper or textiles, or as building materials. In polymer solar cells a combination of two materials are used, an electron donor and an electron acceptor. The three dimensional distribution of the donor and acceptor in the active layer of the device, i.e. the morphology, is known to have larger influence of the solar cell performance. For the optimal morphology there is a trade-off between sometimes conflicting criteria for the various steps of the energy conversion process. The dissociation of photogenerated excitons takes place at an interface between the donor and acceptor materials. Therefore an efficient generation of charges requires a large interface between the two components. However, for charge transport and collection at the electrodes, continuous pathways for the charges to the electrodes are required.</p><p>In this thesis, results from morphology studies by atomic force microscopy (AFM) and dynamic secondary ion mass spectrometry (SIMS) of spin-coated blend and bilayer thin films of polyfluorene co-polymers, especially poly[(9,9-dioctylfluorenyl-2,7-diyl)-co-5,5-(4´,7´-di-2-thienyl-2´,1´,3´-benzothiadiazole)] APFO-3, and the fullerene derivative [6,6]-phenyl-C61-butyric acid methyl ester (PCBM) are presented. It is shown that by varying the blend ratio, the spin.-coating solvent, and/or the substrate, different morphologies can be obtained, e.g. diffuse bilayer structures, spontaneously formed multilayer structures and homogeneous blends. The connection between these different morphologies and the performance of solar cells is also analysed. The results indicate that nano-scale engineering of the morphology in the active layer may be an important factor in the optimization of the performance of polymer solar cells.</p> Polymer Solar Cells Polymer Blends Morphology Polyfluorene PCBM AFM SIMS Spin-Coating Surface Directed Spinodal Decomposition Physics Fysik

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