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Growth of Zinc Oxide Nanoparticles on Top of Polymers and Organic Small Molecules as a Transparent Cathode in Tandem Photovoltaic DeviceAl Kadi Jazairli, Mohamad January 2008 (has links)
<p>Organic solar cells have caught considerable attention in the past few years due to their potential for providing environmentally safe, flexible, lightweight, inexpensive, and roll-to-roll feasible production solar cells. However, the efficiency achieved in current organic solar cells is quite low, yet quick and successive improvements render it as a promising alternative. A hopeful approach to improve the efficiency is by exploiting the tandem concept which consists of stacking two or more organic solar cells in series.</p><p>One important constituent in tandem solar cells is the middle electrode layer which is transparent and functions as a cathode for the first cell and an anode for the second cell. Most studies done so far have employed noble metals such as gold or silver as the middle electrode layer; however, they suffered from several shortcomings especially with respect to reproducibility.</p><p>This thesis focuses on studying a new trend which employs an oxide material based on nano-particles as a transparent cathode (such as Zinc-oxide-nano-particles) along with a transparent anode so as to replace the middle electrode.</p><p>Thus, this work presents a study on solution processable zinc oxide (ZnO) nanostructures, their proper handling techniques, and their potential as a middle electrode material in Tandem solar cells in many different configurations involving both polymer and small molecule materials. Moreover, the ZnO-np potential as a candidate for acceptor material is also investigated.</p>
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Device physics of organic field effect transistors and organic photovoltaic devicesDunn, Lawrence Robert 28 April 2014 (has links)
In this dissertation novel work is presented showing the performance and device physics of Organic Field Effect Transistors (OFETs) and bulk heterojunction Organic Photovoltaic (OPV) devices fabricated using novel acceptor small molecules. Pentacene and N,N’-bis(n-octyl)-dicyanoperylene-3,4:9,10-bis(dicarboximide) (PDI-8CN₂) were used as the active layer in p-channel and n-channel Organic Field Effect Transistors (OFETs), respectively, and novel pulsed voltage transient measurements were developed in order to extract transient mobilities and carrier velocities from the transistor response of the device, which were well correlated with the corresponding DC OFET characteristics. A distributed RC network was used to model the OFET’s channel and the transient and DC characteristics of the devices were successfully reproduced. Temperature dependent studies of the DC field effect mobilities and transient mobilities of these two materials were carried out and the results used to extract information on charge carrier transport in the materials at varying time scales. Open-circuit voltages of the OPV devices are correlated with the Highest Occupied Molecular Orbital (HOMO) and Lowest Unoccupied Molecular Orbital (LUMO) levels various acceptor small molecules and donor polymers comprising the active layers of the devices. / text
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Niemann-Pick C1 Is Essential for Ebola Virus Infection and a Target of Small Molecule InhibitorsBruchez, Anna 03 April 2013 (has links)
Ebolavirus (EboV) is a highly pathogenic enveloped virus that causes outbreaks of zoonotic infection in Africa. The clinical symptoms are manifestations of the massive production of pro-inflammatory cytokines in response to infection and in many outbreaks, case fatality rate exceeds 75%. The unpredictable onset, ease of transmission, rapid progression of disease, high mortality and lack of effective vaccine or therapy have created a high level of public concern about EboV. Here we report the properties of a benzylpiperazine adamantane diamide-derived compound identified in a screen for inhibitors of EboV infection. We found that the inhibitor is specific, reversible, and that the target(s) for inhibition are present in cells and not in virus particles. The compound is not an inhibitor of acid pH-dependent endosome protease activity, which is required for EboV infection. Treatment of cells with this compound causes accumulation of cholesterol in late endosomes and lysosomes (LE/LY), suggesting it inhibits one or more proteins involved in regulation of cholesterol uptake into cells. Using mutant cell lines and informative derivatives of the inhibitor, we found the inhibitor target is the endosomal membrane protein Niemann-Pick C1 (NPC1). NPC1 is a polytopic LE/LY membrane protein that mediates uptake of lipoprotein-derived cholesterol into cells. We find that NPC1 is essential for EboV infection, that NPC1 binds to the protease-cleaved GP1 subunit of the EboV glycoprotein, and that the anti-viral compound inhibits infection by targeting NPC1 and interfering with binding to GP1. Furthermore, analysis of viral variants resistant to the anti-viral compound revealed that the residues which confer resistance are located on the surface of the receptor binding domain of GP1. Combined with the results of previous studies of GP structure and function, our findings support a model of EboV infection in which cleavage of the GP1 subunit by endosomal cathepsin proteases removes heavily glycosylated domains to expose the N-terminal domain, which is a ligand for NPC1 and regulates membrane fusion by the GP2 subunit. Thus, NPC1 is essential for EboV entry and a target for anti-viral therapy.
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New insights into targeting the androgen receptor for cancer therapy: from selective delivery of gold nanoparticles and histone deacetylase inhibitors, to potent antagonists and inverse agonistsGryder, Berkley Eric 12 January 2015 (has links)
Cancer is the second leading cause of death in the United States (more than half a million people each year), and even with billions of dollars in medical effort patients are rarely cured. This dissertation research is devoted to meeting this medical need by providing new cancer therapeutics that are more potent and safer than current chemotherapies. This is achieved by using two state of the art anticancer “warheads”: 1) gold nanoparticle (AuNP) technology and 2) a new class of epigenetic anticancer small molecules, histone deacetylase inhibitors (HDACi). These warheads are then selectively delivered to cancer cells via “homing devices” targeted to receptors that are overexpressed in the cancers.
This work primarily focuses on the androgen receptor (AR) to target prostate cancer.
The 1st chapter sets the stage, providing scientific rationale and background for the central hypothesis: small molecules that engage the AR can, upon conjugation to a therapeutic agent, enable selective delivery of that agent to prostate cancer cells.
Chapter 2 delves into the structural molecular biology of the androgen receptor. There is a survey of the crystallographic data for all nuclear receptors, providing structural information which is used to build AR homology models for antagonist and inverse agonist modes of ligand binding. These models are used to design AR targeting ligands (Chapters 3, 5, 6 and 7).
The application of the targeting technology is illustrated by attaching them to AuNPs for selective delivery to prostate cancer cells (Chapter 3). Next, in order to appreciate the importance of using targeting agents in HDACi cancer therapeutics, we reviewed this recently emerged field in Chapter 4. In this chapter we argue that the failure of HDACi in solid tumors, despite more than 500 clinical trials in the last decade, is primarily due to an inability of these small molecules to accumulate at effective concentrations in the cancer. We provide an analysis of the paradigms being pursued to overcome this barrier, including HDAC isoform selectivity, localized administration, and targeting cap groups to achieve selective tissue and cell type distribution. In Chapter 5, this last approach (targeting cap groups, or a “homing device”) is illustrated with HDACi targeted to prostate cancer via antiandrogens that bind the AR. The second generation of improved “homing devices” is disclosed in Chapter 6 (for both AuNPs and HDACi), in addition to preliminary ADMET data and safety studies in mice.
Excitingly, our three dimensional understanding of binding to the AR allowed design and structure-activity-relationship studies that lead to the first reported examples of AR inverse agonists (Chapter 7)
Several points of significance:
• AuNP targeted to AR
∙ have the strongest binding affinity ever reported (IC50 ~14 picomolar)
∙ are actively recruited to prostate cancer cells
∙ overcome treatment resistance in advanced prostate cancer cells
∙ exhibit nanomolar anticancer potency
∙ resolved the identity of the “membrane AR” as the GPRC6A
• HDACi targeted to AR
∙ have HDACi activity and AR binding affinity superior to their clinical precursors
∙ exhibit potent AR antagonist activity
∙ induce AR translocation to the nucleus in a HDACi dependent fashion
∙ selectively and potently kill prostate cancer cells that express AR
∙ are safer than Tylenol®, as tested in small animals
• Pure AR binding ligand studies
∙ resulted in the discovery of the first examples of AR inverse agonists, which are vastly more potent that clinically available antiandrogens for prostate cancer
∙ work via a never-before-seen mechanism of action, by localizing to the nucleus and recruiting corepressors to actively shut off AR genes
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Mechanistic Studies of Orthogonal Transformations of Bis-Vinyl Ethers: Modular Access to Complex Small MoleculesO'Rourke, Natasha Felicia 20 November 2014 (has links)
Efficient access to molecular complexity and diversity is important for the development of small-molecule screening libraries designed to identify highly specific modulators of disease relevant macromolecular interactions. We envisioned the use of iteratively synthesized bis-vinyl ether substrates for cascade-type transformations to gain rapid access to several different classes of stereochemically rich, linear or polycyclic scaffolds. To evaluate their utility in this context, mechanistic investigations were undertaken to understand the chemical reactivity of bis-vinyl ethers in radical cyclization reactions and [3,3]-sigmatropic rearrangements.
Radical cyclization across bis-vinyl ethers proceeded through an apparent 6-endo-trig/5-exo-trig ring closure to afford functionalized hexahydro-2H-furo[3,4-b]pyrans in good yield, with high diastereoselectivity and excellent regiocontrol. Combination of two electron-withdrawing substituents on the bis-vinyl ether backbone resulted in the trapping of a 5-exo-trig/β-scission product, prompting us to investigate the mechanism for cyclization. Formation of the hexahydrofuropyrans was found to be the result of a 5-exo-trig/3-exo-trig/retro-3-exo-trig pathway to afford a “formal” 6-endo pyranosyl radical that could participate in a second 5-exo-trig cyclization to secure the two ring system.
From this earlier study, we found certain combinations of substituents on the bis-vinyl ether backbone increased the propensity for these substrates to undergo Claisen rearrangement at remarkably low temperatures. Kinetic investigations of the substituent effects influencing bis-vinyl ether stability found that electron-releasing substituents on the γ-allyloxy fragment increased the rate of rearrangement as a result of stabilization of a cationic allyl fragment in the transition state. Thermochemical data derived from the earlier kinetic investigations also indicated that the Claisen rearrangement of bis-vinyl ether substrates occured through a dissociative mechanism, characterised by an ΔS‡ of +2.3 cal K-1 mol-1.
A palladium-catalyzed auxiliary-controlled diastereoselective Claisen rearrangement of bis-vinyl ethers to access aldol-type products is currently under development. Preliminary results indicate that a modest degree of diastereoselectivity can be achieved in this reaction, provided that the steric burden at the stereogenic element is close enough to the pericyclic framework to exert an influence on facial selectivity. / Graduate
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Développement de nouveaux inhibiteurs du TNFα identifiés par Drug Design / Development of new TNFalpha inhibitors identified by drug designMouhsine, Hadley 29 October 2012 (has links)
Les anticorps monoclonaux ont constitué une révolution dans le traitement desmaladies inflammatoires chroniques, mais ils présentent des inconvénients majeurs (effetssecondaires, coûts élevés, résistances).Notre équipe développe des inhibiteurs du TNFα par deux approches : immunisationactive contre des peptides de cytokine pour générer des anticorps neutralisants et petitesmolécules chimiques pouvant inhiber directement le TNFα.J’ai évalué in vitro les meilleurs composés d’un criblage de chimiothèque in silico, etnotamment identifié une petite molécule qui a protégé les animaux dans deux modèles demaladies in vivo (choc septique et colite au DSS). J’ai aussi réalisé l’analyse d’analogueschimiques des meilleurs composés identifiés in vitro.J’ai également évalué l’immunogénicité de plusieurs peptides de TNFα mais lesanticorps générés n’étaient pas neutralisants in vitro et nous n’avons donc pas testé lespeptides in vivo.Mon travail s’est situé à l’interface de la bioinformatique, de la chimie, et de labiologie et m’a permis de bien comprendre les enjeux du développement moderne dumédicament. / Monoclonal antibodies have been a revolution for the treatment of chronicinflammatory diseases but present several drawbacks (secondary effects, prohibitive costs,resistance)Our team develops TNFα inhibitors using two approaches : active immunizationagainst cytokine peptides and small compounds having a direct inhibition on TNFα.I have evaluated in vitro the best compounds selected after in silico screening of achemical library and I have identified a small molecule which was protective in two animalmodels (septic shock and DSS induced colitis). I have also analyzed chemical analogues ofthe best compounds found in vitro.I have also tested the immunogenicity of TNFα peptides but they did not yieldneutralizing antibodies in vitro, and we thus did not test them in vivo.My work was at the interface of bioinformatics, chemistry and biology, and this hasenabled me to understand the key issues in the modern development of drugs.
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Conception et réactivité de complexes mono- et polymétalliques d'éléments f en bas degré d'oxydation / Design and reactivity of mono- and polymetallic complexes of low valent f-elementsCamp, Clément 20 September 2013 (has links)
Au-delà de son importance dans l’industrie nucléaire, la chimie d’oxydoréduction de l’uraniumretient de plus en plus l’attention des chercheurs. En effet, la capacité toute particulière descomplexes d’uranium à bas degré d’oxydation à promouvoir des réductions originales par desvoies inhabituelles suscite actuellement un grand intérêt, tout particulièrement leur aptitude àactiver dans des conditions douces des petites molécules telles CO, CO2, N2, ou encore descomposés aromatiques et des azotures. Les composés d’uranium, de part leurs propriétés decoordination tout à fait uniques pourraient offrir une alternative aux métaux de transitionclassiques pour la conception de catalyseurs. Cependant, comparativement aux métaux du bloc d,les processus polyélectroniques sont rares dans la chimie de l’uranium à bas degré d’oxidation quiest dominée par les transferts monoélectroniques. C’est pourquoi le développement de nouveauxcomplexes d’uranium capables de réaliser des réductions poly-électroniques est particulièrementintéressant. Le premier objectif de ce travail était d’associer à l’uranium des ligands non-innocentsservant de réservoir d’électrons. Ainsi nous avons utilisé des bases de Schiff p-conjuguées pourexplorer la chimie de cet élément à bas degree d’oxydation. Cela nous a permis d’isoler descomplexes riches en électrons dans lesquels des électrons sont stockés sur le ligand via laformation de liaisons C-C. Ces mêmes liaisons sont rompues en présence d’agent oxydant, et lesélectrons sont libérés pour réaliser des transformations polyélectroniques. Ce procédé a étéobservé pour plusieurs bases de Schiff, permettant de moduler les propriétés des composés. Dansune seconde approche, nous nous sommes intéressés à la synthèse et à l’étude de la réactivité denouveaux complexes d’uranium trivalent supportés par des ligands silanolates. De nouveauxcomposés dinucléaires d’uranium à basse valence ont été obtenus. Ces composés très réactifsdécomposent spontanément en clivant des groupements tertiobutyls des ligands, conduisant à laformation de complexes d’uranium(IV). En parallèle, un complexe monoanionique mononucléaired’U(III) a été isolé, nous permettant de comparer la réactivité de l’uranium trivalent dans différentsenvironnements stériques et électroniques. Ces études de réactivité ont permis de stabiliser unexemple rare de dimère d’uranium ponté par un groupement CS22- et ont mis en évidence lacapacité de l’uranium trivalent à promouvoir la dismutation de CO2 en carbonate et CO. La réactionde ces composés d’uranium trivalent vis-à-vis d’azotures organiques et inorganiques a produit denouveaux nitrures et nitrènes d’uranium originaux. Enfin, la capacité de ces agents réducteurspuissants à transférer des électrons au toluène a permis d’isoler une famille de complexessandwiches inversés où deux cations uranium sont liés de part et d’autre d’un cycle aromatique. / Beyond its importance in nuclear industry the redox chemistry uranium is attracting increasinginterest because complexes of low-valent uranium can promote unusual reductive chemistrythrough unusual reaction pathways, including attractive examples of CO, CO2, N2, arenes andazides activation in mild condition. Due to the unique coordination and bonding properties ofuranium, its compounds could provide an attractive alternative to transition metals for thecatalytic transformation of small molecules. However, metal-based multi-electron processesremain uncommon in uranium chemistry especially in comparison with the d-block metals, thechemistry of low-valent uranium being dominated by single-electron transfers. In this context, thefirst aim of this project was to investigate the association of low-valent uranium to a non-innocentligand acting as an independent electron reservoir at a same molecule. Accordingly, weinterrogated the use of highly p-delocalized Schiff bases ligands for supporting low-valent uraniumchemistry. This led to the isolation of electron-rich complexes which are stabilized by storingelectrons on the ligands through the formation of C-C bonds. Interestingly, these C-C bonds can becleaved by oxidizing agents and the electrons released to participate in multi-electron redoxreactions. This process was observed within different Schiff-base ligand scaffolds, allowing atuning of the properties of the compounds. The second part of this work was dedicated to thesynthesis of novel trivalent uranium complexes supported by siloxy ligands and the study of theirredox reactivity and coordination properties. Novel dinuclear highly-reactive low-valent uraniumassemblies were developed. The study of their limited stability revealed that these compounds arespontaneously decomposing through the cleavage of tBu groups from the supporting ligandsresulting in the formation of U(IV) species. In parallel, a mononuclear trivalent uranium atecomplex was obtained, allowing to compare the reactivity of U(III) in different steric and electronicenvironements. Hence we became interested in studying the redox reactivity of these compoundswith different substrates including CO2, CS2, azides and arenes. These investigations led to thestabilization of a rare CS22- sandwich complex of uranium, and highlited the ability of U(III) topromote reductive disproportionation of CO2 to carbonate and CO. The reaction of these trivalenturanium siloxide species with organic and inorganic azides produced original uranium imidos andnitridos compounds with original topologies. Finally the capacity of these strongly reducing agentsto transfer electrons to the toluene fragment lead to the isolation of a family of arenes invertedsandwich complexes.
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Introdução a cristalografia geométrica e determinação de estruturas de pequenas moléculas por difração de raios-X / Introduction to crystallographic symmetry and determination of small molecules structures by X-ray diffractionClaudio Barberato 21 October 1992 (has links)
Foram determinadas quatro estruturas de complexos de Lantanóides utilizando a difração de raios-X. As intensidades dos feixes difratados foram medidas com um difratômetro automático de 4 ciclos CAD-4. As estruturas foram resolvidas utilizando o método de Patterson, sínteses de Fourier e Fourier Diferença e refinadas por métodos de mínimos quadrados com matriz bloqueada. Os poliedros de coordenação foram obtidos considerando as distâncias quadráticas médias mínimas entre os coordenantes e poliedros ideais. Y(C6H2N3O)3(6H18N3OP)2 e Ho(C6H2N3O)3(C6H18N3OP)2 são complexos isomorfos pertencentes ao sistema monoclínico, P21/n, tendo como parâmetros de rede para o complexo de Y: a = 17.104(2), b = 16.328(1), c = 17.671(6) Å, β = 95.40(1)°, Z = 4, Dc = 1.53 gcm-3, V = 4913(4) ޵ e para o complexo de Ho: a = 17.097(2), b = 16.299(1), c = 17.685(3) Å, β = 95.41(1)°, V = 4907(2) ޵, Dc = 1.63 gcm-3. O poliedro de coordenação para esses complexos é o dodecaedro, simetria D2d (42m). Ce(C6H2N3O)3(C5H12N2O)3, é uma estrutura pertencente ao sistema triclínico, P-1, a = 1.495(5), b = 11.815(5), c = 18.40(1)Å, α = 83.09(5)°, β = 76.7995)°, γ = 77.00(3)°, Z = 2, V = 4800(2)޵, Dc = 1.63 gcm-3. Existem 8 coordenantes ao redor do átomo pesado formando um Prisma Trigonal Biencapuzado. Nd(C6H2N3O)3(C5H12N2O)3, pertence ao sistema monoclínico, P21/c, a = 18.913(5), b = 12.386(5), c = 22.134(5)Å, β = 120.20(5)°, V = 4800(2)޵, Dc = 1.63 gcm-3. O número de coordenação é igual a 9 e o poliedro de coordenação é uma forma intermediária entre o antiprisma quadrado monoencapuzado e o prisma trigonal Trigonal Triencapuzado. / It were determinated four small molecules structures by X-Ray diffraction. The intensities of the reflections were measured with an automatic four-cicle difractometer CAD-4. The structures were solved by Patterson, Fourier Synthesis and refined by least squares methods. The coordination polyedras were obtained considering the minimal root mean distances between the polyedras founded and the ideal polyedras. Y(C6H2N3O)3(6H18N3OP)2 e Ho(C6H2N3O)3(C6H18N3OP)2 are isomorphos strutures belong to the monoclinic system, P21/n; Y: a = 17.104(2), b = 16.328(1), c = 17.671(6) Å, β = 95.40(1)°, Z = 4, Dc = 1.53 gcm-3, V = 4913(4) ޵ Ho: a = 17.097(2), b = 16.299(1), c = 17.685(3)Å, β = 95.41(1)°, V = 4907(2)޵, Dc = 1.63 gcm-3. The coordination number of these structures is 8 and the coordination polyedra is dodecahedro, with simetry D2d (42m). Ce(C6H2N3O)3(C5H12N2O)3, is a structure belongs to the triclinic system. P-1, a = 1.495(5), b = 11.815(5), c = 18.40(1)Å, α = 83.09(5)°, β = 76.7995)°, γ = 77.00(3)°, Z = 2, V = 4800(2)޵, Dc = 1.63 gcm-3. There are 8 coordinates around the heavy metal forming a Two-couped Trigonal Prism. Nd(C6H2N3O)3(C5H12N2O)3, belongs to the monoclinic system, P21/c, a = 18.913(5), b = 12.386(5), c = 22.134(5)Å, β = 120.20(5)°, V = 4800(2)޵, Dc = 1.63 gcm-3. The coordination number is a 9 and the coordination polyedra is intermediate between mono-couped square antiprism and three-couped trigonal.
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Interação de pequenas moléculas com proteínas: um estudo usando métodos convencionais e transferência de saturação de R.P.E. / On the interaction of small molecules with proteins: a conventional EPR and ST-EPR studyJoao Ruggiero Neto 20 June 1984 (has links)
Neste trabalho, analisamos a interação de pequenas moléculas, marcadores hidrofóbicos, com hemoglobina, em diferentes estados: monocristal, pó e solução aquosa. Os métodos de análise empregados, são baseados nas teorias de relaxação em líquidos e técnicas não lineares de ressonância ST-RPE (transferência de saturação), fornecendo informações sobre mudanças locais nas vizinhanças desses marcadores. Um dos marcadores hidrofóbicos, o TEMPO, mostrou uma anisotropia considerável nos espectros de RPE do monocristal de hemoglobina que está relacionado com o empacotamento molecular da proteína do cristal. A associação desses métodos de análise conduziu a importantes informações sobre mudanças na camada de hidratação em várias proteínas: hemoglobina, mioglobina e lisozima, monitoradas pelo marcador covalente derivado da maleimida, e induzidas pela temperatura, sob diferentes condições de hidratação. Desta forma o uso da espectroscopia de RPE especialmente com simulação espectral e DT-RPE mostro ser um método potente e ainda não explorado no estado de hidratação de proteínas / In this work, the interactions of small molecules, hydrophobic spin labels, with hemoglobin, under different states was analysed: single crystal, powder and aqueous solution. The methods of analysis employed, are based in relaxation theory in liquids and non-linear techniques, saturation transfer (ST-EPR), giving informations on the local changes in neighbourhood of the labels. One of the hydrophobic labels, TEMPO, showed a considerable anisotropy in the hemoglobin single crystal spectra, a result related to the molecular packing in the protein single crystal. The association of the techniques of analysis all together lead to important informations an temperature induced changes in the hydration layer in several proteins: hemoglobin, myoglobin, NEM*, a maleimide derivated, in different conditions of hydration. In this way the use of EPR spectroscopy and particularly with spectral simulations and ST-EPR, proved to be a powerful and not yet very much explored method to study the problem of protein hydration
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Solution-processable oligomeric and small molecule semiconductors for organic solar cells / Oligomères et petites molécules semi-conducteurs déposables par voie-liquide pour les cellules solaires organiquesLe Borgne, Mylène 28 April 2016 (has links)
Les cellules solaires organiques sont une technologie très prometteuse grâce à leur faible-coût de fabrication, leur flexibilité et leur légèreté. Actuellement, elles ne sont qu’au stade du prototype à cause de leurs faibles rendements et leur courte durée de vie. L’une des voies les plus étudiées pour améliorer le rendement est la conception de nouveaux matériaux photo-actifs. Lors de cette thèse, deux séries de semi-conducteurs donneurs d’électrons. La première série comprend trois oligomères, chacun composé de trois unités de diketopyrrolopyrrole (DPP) qui est un chromophore très étudié dans la littérature. Ces oligomères ont la particularité d’absorber dans le proche infra-rouge. En intercalant différents groupements donneurs d’électrons entre les DPPs, différentes torsions sont obtenues le long de leur squelette. Ceci a permis d’établir qu’un oligomère plan a une plus grande cristallinité et par conséquent transporte mieux les charges, atteignant une mobilité de trou de 10-3 cm². V-1.s-1. Cependant, cette forte cristallinité entraîne une hétérojonction volumique défavorable et un faible rendement photovoltaïque (<1%). La deuxième série est composée de quatre petites molécules combinant une unité 3,3’-(ethane-1,2-diylidene)bis(indolin-2-one) (EBI) avec différents groupements donneurs d’électrons: thiophène (EBI-T), benzofurane (EBI-BF) and bithiophène (EBI-2T)). Les dérivés EBI ont été testés dans les transistors à effet de champ et dans les cellules solaires en tant que semi-conducteurs donneurs. La meilleure mobilité de trou de 0,021 cm².V-1.s-1 a été mesurée avec EBI-BF grâce à sa conformation plane alors que le PCE maximal de 1.92% est obtenu avec EBI-2T grâce à son large spectre d’absorption et une morphologie adéquate. / Organic solar cells appear as a promising technology within photovoltaic field owing to their low-cost fabrication and their great flexibility enabling a widespread distribution. For now, they are still at the prototype stage due to their limited efficiency and lifetimes. Many efforts were realized in designing new materials as they are involved in every steps of the photovoltaic process and thus they dictate the cell efficiency. Along this thesis, two series of electron-donating semi-conductors were designed and synthesized. The first series consist in three oligomers containing three diketopyrrolopyrrole units, a well-studied chromophore. Those oligomers absorb up to the near infra-red region, a very interesting feature for light harvesting. Through the engineering of electron-rich spacers, various twists were generated in the oligomers backbone. The oligomer showing a coplanar conformation appears to be the most crystalline and thus exhibits the best charge transport properties with a hole mobility of 10-3 cm².V-1.s-1.iiiHowever, bulk heterojunction organic solar cells, this high crystallinity results in an unfavorable morphology and a PCE inferior to 1%. As for the second series, the four small molecules combined 3,3’-(ethane-1,2-diylidene)bis(indolin-2-one) (EBI), an electron deficient unit, and various electron-rich units such as thiophene (EBI-T), benzofuran (EBI-BF) and bithiophene (EBI-2T). Among EBI derivatives, EBI-BF demonstrated the highest hole mobility of 0.021 cm².V-1.s-1 in field effect transistors due to its coplanar conformation. Meanwhile, in bulk heterojunction solar cells, the highest PCE of 1.92% was obtained with EBI-2T:PC61BM blend owing to a more appropriate morphology and the broadest absorption spectrum of EBI-2T.
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