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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
51

PHOTOCHEMISTRY AND PHOTOPHYSICAL CHARACTERIZATION OF PORPHYRIN & N-CONFUSED PORPHYRIN DYADS: PORPHYRIN PHOTOPHYSICAL PROPERTIES AND ELECTRON AND ENERGY TRANSFER

Alemán, Elvin A. January 2006 (has links)
No description available.
52

Unique Morphology and Structure of New Organic Porphyrin Based Discotic Liquid Crystals

Kulkarni, Rahul 21 May 2010 (has links)
No description available.
53

Electronic Studies into Silver(III) N-Confused Tetraphenylporphyrin

Wagner, Jenna 02 May 2023 (has links)
No description available.
54

REACTIVITY AND EQUILIBRIUM THERMODYNAMIC STUDIES OF IRIDIUM PORPHYRINS IN WATER AND ALCOHOL

Bhagan, Salome January 2012 (has links)
Environmental and energy issues have stimulated renewed interest in utilizing both water and methanol as reagents and reaction mediums. Our current interest is to evaluate the scope of group nine organometallics and establish thermodynamic parameters for their reactivity in aqueous solvent. A comprehensive thermodynamic database for a wide scope of organo-rhodium transformations in a range of reaction media including benzene, water, and methanol has been well established by our group. Aqueous solutions of rhodium porphyrin have been determined to manifest an exceptional range of substrate reactions with carbon monoxide, dihydrogen, olefins, methanol and aldehydes. This study will focus on expansion of the thermodynamic database to all the group nine metals, particularly the iridium porphyrin systems in both water and methanol. Substrate reactivity and development of new mechanistic strategies for the conversion of carbon monoxide, alkanes, and alkenes to organic oxygenates are central objectives. Water/Methanol soluble porphyrin iridium complexes including iridium tetrakis(p-sulfonatophenyl)porphyrin ((TSPP)Ir) and iridium tetrakis(3,5-sulfonatomesityl)porphyrin ((TMPS)Ir) derivatives can be prepared by sulfonation of tetra phenyl porphyrin (H2TPP) and tetra mesityl porphyrin (H2TMP). The reactivity of dihydrogen with aqueous solutions of iridium(III) tetrakis(p-sulfonatophenyl)porphyrin ((TSPP)Ir(III)) complexes produce equilibrium distributions between six iridium species including iridium hydride ([(TSPP)Ir-D(D2O)]-4), iridium(I) ([(TSPP)IrI(D2O)]-5), and iridium (II) dimer ([(TSPP)IrII(D2O)]2-8) complexes. Each of these types of iridium porphyrin species including Ir(I), Ir(II), Ir(III), Ir-H, and Ir-OH function as precursors for a range of organometallic substrate reactions. A primary objective is to define the quantitative relationships pertaining to the distribution of species in aqueous solution as a function of the dihydrogen and hydrogen ion concentrations through direct measurement of five equilibrium constants along with free energy changes of coordinated water and free energy changes of reactions of dihydrogen in water. Reactivity, kinetics and evaluation of equilibrium thermodynamics, including the reactions of iridium hydroxide and methoxide with olefins to produce beta-hydroxyalkyl and beta-methoxyalkyl complexes, reactions of iridium hydride and olefins to produce iridium alkyl complexes, and reactions of iridium hydride with carbon monoxide to produce iridium formyl [Ir-CHO] complexes are also objectives of this research. Another research goal is the design and synthesis of diporphyrin ligands that form dimetal complexes capable of preorganizing transition states for substrate reactions that involve two metal centers. Dirhodium dimetalloradical complexes are observed to manifest large rate increases over mono-metalloradical activation reactions of hydrogen, methane, and other small molecule substrates. In this study, synthesis of diporphyrin (bisporphyrin) ligands and other ligands which will permit dimetallo complexes like anti-aromatic [14]annulene and low steric porphine ligands will be also be examined. / Chemistry
55

Visible-Light Generation of High-Valent Metal-Oxo Intermediates and a Biomimetic Oxidation Catalyzed By Manganese Porphyrins with Iodobenzene Diacetate

Kwong, Ka Wai 01 October 2016 (has links)
High-valent iron-oxo intermediates play central roles as active oxidants in enzymatic and synthetic catalytic oxidations. Many transition metal catalysts are designed for biomimetic studies of the predominant oxidation catalysts in Nature, the cytochrome P450 enzymes. In this work, a new photochemical method to generate high-valent iron-oxo porphyrin models was discovered. As controlled by the electronic nature of porphyrin ligands, iron(IV)-oxo porphyrin radical cations (Compound I model) and iron(IV)-oxo porphyrin derivatives (Compound II model) were produced. These observations indicate that the photochemical reactions involve a heterolytic cleavage of O-Br in precursors to give a putative iron(V)-oxo intermediate, which might relax to Compound I through electron transfer from porphyrin to the iron or undergo rapid comproportionation reaction with residual iron(III) to afford the Compound II derivative. Furthermore, visible light photolysis of bis-porphyrins-dimanganese(III)-μ-oxo complexes, [MnIII(Por)]2O, was studied in three porphyrin systems. Direct conversion of manganese(III)-μ-oxo dimers to manganese(IV)-oxo porphyrins [MnIV(Por)(O)] and manganese(III) products was observed in benzene solution upon light irradiation. The spectral signature of [MnIV(Por)(O)] was further confirmed by production of the same species in the reported reaction of the [MnIII(Por)Cl] with PhI(OAc)2. Continuous irradiation of bis-porphyrins-dimanganese(III)-μ-oxo complexes in the presence of pyridine or triphenylphospine gave rise to the formation of [MnII(Por)(Py)] or [MnII(Por)(PPh3)], which are stable to be detected. A photo-disproportionation mechanism similar to that for bis-porphyrins-diiron(III)-μ-oxo complex was proposed to explain above photochemical behaviors of bis-porphyrins-dimanganese(III)-μ-oxo complexes. With iodobenzene diacetate [PhI(OAc)2] as the oxygen source, manganese(III) porphyrin complexes exhibit remarkable catalytic activity towards the selective oxidation of alkenes and activated hydrocarbons. Conspicuous is the fact that the readily soluble PhI(OAc)2 in the presence of a small amount of water is more efficient oxygen source than the commonly used PhIO under same conditions. High selectivity for epoxides and excellent catalytic efficiency with up to 10,000 Turnovers (TONs) were achieved in alkene epoxidations. A manganese(IV)-oxo porphyrin was observed in the oxidation of the manganese(III) porphyrin and PhI(OAc)2. However, catalytic competition and Hammett studies suggested that the more reactive manganese(V)-oxo intermediate was favored as the premier active oxidant, even it is too short-lived to be detected in the catalytic reaction.
56

Transfert de charge et d’énergie dans les dyades et oligomères de porphyrine / Charge and energy transfer in porphyrin dyads and oligomers

Abdelhameed, Mohammed January 2014 (has links)
Résumé : Le travail de recherche présenté dans ce mémoire fut inspiré par le processus de la photosynthèse qui se produit chez les plantes. Au cours de ce processus l’énergie solaire est convertie en énergie chimique via différentes étapes de transferts d’électrons et d’énergie. En maîtrisant bien ces concepts, de nombreuses applications, telles que les cellules photovoltaïques ou les DEL (Diodes électro-luminescentes) peuvent être améliorées. Pour se faire, il est important d’optimiser les propriétés des matériaux existants (oligomères, polymères, etc…) en préparant des systèmes conjugués plus efficaces, mais aussi de pleinement comprendre les processus qui s’y produisent (processus de transferts d’électrons et d’énergie photo-induist). La série d’oligomères et de polymères présentée dans ce mémoire le sont pour leurs applications dans des systèmes photoniques. Dans cette optique, ce mémoire a été divisé en cinq grands chapitres. Le premier présente les principes théoriques de la photophysique. Le second présente le suivi du transfert d’énergie T[indice inférieur 1] dans les états triplets, T[indice inférieur 1], une dyade constituée de la tétraphénylporphyrine de zinc(II), [ZnTPP], et de la bis(phénylpyridinato)(bipyridine) d’iridium(III), [Ir], chromophores liés avec un pont trans-diéthynylbis(phosphine)-platine(II). Malgré que cette dyade soit entièrement conjuguée et qu’elle soit constituée d’un donneur ([ZnTPP]) et d’un accepteur ([Ir]), aucun transfert d’énergie T[indice inférieur 1] [Ir] → S[indice inférieur 1]/T[indice inférieur 1] [ZnTTP] n’a été observé. Ce résultat fut attribué à l’absence de recouvrement des orbitales moléculaires entre la HSOMO(donneur*) et la HSOMO(accepteur), LSOMO(accepteur) and LSOMO (donneur*) (mécanisme de Dexter). Ainsi, l’échange d’électrons est impossible. Ce chapitre suggère que l’équation de Dexter, k[indice inférieur Dexter] = KJexp(-2r[indice inférieur DA]/L) ne reste qu’une approximation. Ce travail a été publié dans ChemComm (2013, 49, 5544-5546). Le troisième chapitre présente le transfert d’énergie singulet beaucoup lent qu’attendu se produisant dans une dyade constituée d’une porphyrine de zinc(II) avec une porphyrine base libre liées par un pont palladium(II) (trans-PdI[indice inférieur 2]). Sachant que cette dyade est entièrement conjuguée et que la distance entre les deux centres de masse des porphyrines est relativement courte, ce système aurait dû présenter un transfert d’énergie très rapide, d’après la théorie de Förster. Dans ce cas, ce comportement a été expliqué par le faible recouvrement des orbitales frontières (OM) du donneur et de l’accepteur. Ce travail a été accepté le 2014-05-26 dans Chemistry – A European Journal (chem.201403146). Le quatrième chapitre rapporte une étude du transfert d’énergie ultra-rapide (650 fs) entre des états singulets dans une dyade composé d’une porphyrine de zinc(II) (le donneur) et une porphyrine base libre (l’accepteur) liées à l’aide d’un pont de palladium ([beta],[beta]--trans-Pd(NH)[indice inférieur 2](CO)[indice inférieur 2]). Ces résultats ont été attribués à la présence d’un couplage fort entre les OM du donneur et de l’accepteur et de la très faible contribution (atomique) du Pd(II) vers ces OM. Cette dyade montre la plus rapide constante de transfert d’énergie k[indice inférieur ET] que nous connaissons pour des dyades similaires contentant un fragment métallique. Les résultats du troisième et quatrième chapitre montrent que la théorie de Förster tel quel ne suffit pas pour prédire les vitesses de transferts d’énergie dans certains systèmes : d’autres facteurs doivent être pris en compte. Ce travail a été soumis dans JACS ( ja-2014-061774, 19-6-2014). Dans le cinquième chapitre de ce mémoire, la synthèse du bis(-[alpha]-(amino(4-éthynylbenzene (triméthylsilane)(R))))bis(4-éthynylbenzene-(triméthylsilane))quinone diimine (R= H, Boc) comme modèle pour des polymères conjugués et non-conjugués contenant le colorant porphyrine a été proposée. Le corps du composé désiré (tétrakis(4-éthynlyphenyl)quinone-1,4-diimine-2,5-diamine) a montré un transfert de charge partant des groupes terminaux riches en électrons une la benzoquinone centrale plus pauvre. La nature de l’émission fut observée uniquement à 77K pour le cas où R = H et fut attribuée à de la fluorescence. À température ambiante, l’intensité était trop faible pour être observée. Dans le cas où R = Boc, aucune emission n’a été détectée. Malheureusement, le composé espéré ne fut pas obtenu, le procédé de synthèse employé engendra uniquement la forme réduite. Cette forme fut malgré tous analysé, et ne présenta pas de transfert de charge ni de communication entre les différents chromophores. Ceci a été expliqué simplement par le fait que la conjugaison est brisée quand ce composé est sous sa forme réduite. Ce travail sera soumis au Journal of Inorganic and Organometallic Polymers and Materials. // Abstract : The research work presented in this master thesis is inspired by the photosynthetic process occurring in plants where solar energy is converted into chemical energy via several energy and electron transfer processes. In the light of these concepts, several applications such as solar cells and light emitting diodes can be improved. To do so, we need to optimize the properties of polyads, oligomers and polymers to device more efficient conjugated materials as well as developing a full understanding of the photo-induced energy and electron transfer processes that occur. Several organometallic oligomers and polymers are presented in this thesis due to their potential photonic applications. In this respect, this master thesis has five chapters. The first one introduces some theoritical principles of photophysics. The second one presents the monitoring of triplet state (T[subscript 1]) energy transfer in a dyad that consists of zinc(II)tetraphenylporphyrin, [ZnTPP], and bis(phenylpyridinato)-(bipyridine)iridium(III), [Ir], chromophores linked by a platinum(II) containing bridge. Despite the conjugation in this dyad and the presence of the [ZnTPP] energy donor and the [Ir] energy acceptor species, no T[subscript 1] [Ir] → S[subscript 1]/T[subscript 1] [ZnTTP] energy transfer occurs. This result was explained by the absence of MO overlap between HSOMO(donor*) and HSOMO(acceptor), LSOMO(donor*) and LSOMO(acceptor) , and hence no efficient double electron transfer exchange (i.e. Dexter mechanism) is likely to occur. This chapter suggested that Dexter formulation, k[subscript Dexter] = KJexp(-2r[subscript DA]/L), appears as an approximation. This work has been published in ChemComm (2013, 49, 5544-5546). The third chapter shows an unexpected slow singlet energy transfer in a dyad built upon a zinc(II)porphyrin and the corresponding free base chromophores linked by a palladium(II)- containing bridge (trans-PdI[subscript 2]), despite the presence of conjugation and the relative short center-to-center distance. This behavior was explained by two factors, the first is the lack of large molecular orbitals (MOs) overlaps between the frontier MOs of the donor and acceptor, and thus preventing a double electron exchange to occur through the trans-PdI[subscript 2] bridge. The second factor affected the energy transfer is the electronic shielding induced by the presence of this same linker, namely the electron rich iodides, preventing the two VI chromophores to fully interact via their transition dipoles. This work has been accepted on 2014-05-26 in Chemistry-A European Journal (chem.201403146). The fourth chapter reports an ultrafast singlet energy transfer (650 fs) in a dyad composed of a zinc(II)porphyrin (donor) and a free base porphyrin (acceptor) [beta],[beta]-linked via trans- Pd(NH)[subscript2](C=O)[subscript 2]. These results were explained by the presence of strong MO couplings of the donor and acceptor and the very weak atomic contribution of the Pd(II) atom to this MO. This dyad shows the fastest energy transfer rate k[subscript ET] among other similar dyad systems incorporating a bridge either in the form of a metal fragment or carbon-based. The results of these third and fourth chapters showed that the Förster mechanism is not enough to account for the energy transfer in some systems and other factors affect that transfer. This work has been submitted in JACS ( ja-2014-061774, 19-6-2014). In chapter 5, the synthesis of bis-[alpha]-(amino(4-ethynylbenzene (trimethylsilane)(R))bis(4- ethynylbenzene-(trimethylsilane))quinone diimine (R = H, Boc) as a model for conjugated and unconjugated porphyrin dye polymers was proposed. The central core of the desired compound, tetrakis(4-ethynlypenyl)quinone-1,4-diimine-2,5-diamine, provided evidence for a charge transfer interaction from the electron richer terminal groups to be more electron poorer benzoquinone ring. The nature of the emission of the core compound was found to be fluorescence at 77K for the case R = H but was too weak to be observed at 298K. No emission was detected for the case R = Boc. Unfortunately, the synthetic route of the desired compound gave the reduced form. The analyses of the reduced compound showed the complete absence of the charge transfer or any communication between the different chromophores due to the broken conjugation between the porphyrin units in the reduced product. This work will be submitted to Journal of Inorganic and Organometallic Polymers and Materials.
57

Anthracene-fused porphyrins

Davis, Nicola Kathleen Sybille January 2011 (has links)
This thesis describes the synthesis of a novel family of porphyrins fused to anthracenes, together with investigations into their optical and electrochemical properties, as well as exploring their potential for application in dye-sensitised solar cells. Chapter 1 gives an overview of the structure-property relationships of large planar pi- systems for organic electronic applications. Porphyrins are introduced as suitable building blocks for such systems, and approaches for extending the pi-conjugation of these macrocycles are presented. A literature review of porphyrins fused to aromatic units is presented in Chapter 2, with a focus on the influence of structure on the optoelectronic properties of such systems. The chapter concludes with a summary of my previous work on the synthesis of anthracene-fused porphyrins, and the aims of this project are stated. Chapter 3 describes the syntheses of fully and partially fused bis-anthracene porphyrin monomers and dimers. By varying peripheral substituents, it was possible to solve problems of aggregation encountered for these systems. Fusion of anthracene units to a porphyrin core was found to result in systems displaying strong absorption in the near-IR, small HOMO-LUMO gaps, and low oxidation potentials. Chapter 4 explores the synthesis, crystal structure and optoelectronic properties of a porphyrin fused to four anthracenes, revealing this system to exhibit the longest wavelength absorption of any porphyrin monomer. The synthesis of a liquid crystalline tetra-anthracene-fused porphyrin was proposed, and attempts to synthesise the necessary anthracene precursors were undertaken. Chapter 5 describes the molecular design and synthetic pathway to a mono-anthracene fused porphyrin, and its unfused analogue, for use in liquid electrolyte dye-sensitised solar cells. By varying the metal oxide layer or lithium ion concentration of the device, it was possible to achieve incident photon to current conversion efficiency (IPCE) responses at wavelengths beyond 1050 nm. Chapter 6 details the experimental synthetic procedures and characterisation data for all the compounds synthesised during this project.
58

Transfert ultrarapide d’électron et transfert modéré d’énergie au sein d’assemblages supramoléculaires de colorants et d’un cluster de palladium / Ultrafast electron and moderate energy transfers within supramolecular assemblies of dyes and a palladium cluster

Luo, Peng January 2016 (has links)
Résumé : Les transferts d’électrons photo-induits et d’énergie jouent un rôle primordial dans un grand nombre de processus photochimiques et photobiologiques, comme la respiration ou la photosynthèse. Une très grande quantité de systèmes à liaisons covalentes ont été conçus pour copier ces processus de transferts. Cependant, les progrès sont, en grande partie, limités par les difficultés rencontrées dans la synthèse de nouveaux couples de types donneurs-accepteurs. Récemment, des espèces utilisant des liaisons non-covalentes, comme les liaisons hydrogènes, les interactions [pi]-[pi], les liaisons de coordination métal-ligands ou encore les interactions électrostatiques sont le centre d’un nouvel intérêt du fait qu’ils soient plus faciles à synthétiser et à gérer pour obtenir des comportements de transferts d’électrons ou d’énergie plus flexibles et sélectifs. C’est dans cette optique que le travail de cette thèse a été mené, i.e. de concevoir des composés auto-assemblés avec des porphyrines et un cluster de palladium pour l’étude des transferts d’électrons photo-induits et d’énergie. Cette thèse se divise en quatre parties principales. Dans la première section, le chapitre 3, deux colorants porphyriniques, soit le 5-(4-carboxylphényl)-10, 15, 20-tristolyl(porphyrinato)zinc(II) (MCP, avec Na+ comme contre-ion) et 5, 15-bis(4-carboxylphényl)-15, 20-bistolyl(porphyrinato)zinc(II) (DCP, avec Na+ comme contre-ion) ont été utilisés comme donneurs d’électrons, et le [Pd3(dppm)3(CO)]2+ ([Pd32+], dppm = (Ph2P)2CH2, PF6‾ est le contre-ion) a été choisi comme accepteur d’électrons. La structure de l’assemblage [Pd32+]•••porphyrine a été élucidée par l’optimisation des géométries à l’aide de calculs DFT. La spectroscopie d’absorption transitoire (TAS) montre la vitesse de transferts d’électrons la plus rapide (< 85 fs, temps inférieurs à la limite de détection) jamais enregistrée pour ce type de système (porphyrine-accepteur auto-assemblés). Généralement, ces processus sont de l’ordre de l’échelle de la ps-ns. Cette vitesse est comparable aux plus rapides transferts d’électrons rapportés dans le cas de systèmes covalents de type porphyrine-accepteur rapide (< 85 fs, temps inférieurs à la limite de détection). Ce transfert d’électrons ultra-rapide (ket > 1.2 × 1013 s-1) se produit à l’état énergétique S1 des colorants dans une structure liée directement par des interactions ioniques, ce qui indique qu’il n’est pas nécessaire d’avoir de forts liens ou une géométrie courbée entre le donneur et l’accepteur. Dans une deuxième section, au chapitre 4, nous avons étudié en profondeur l’effet de l’utilisation de porphyrines à systèmes π-étendus sur le comportement des transferts d’électrons. Le colorant 9, 18, 27, 36-tétrakis-meso-(4-carboxyphényl)tétrabenzoporphyrinatozinc(II) (TCPBP, avec Na+ comme contre-ion) a été sélectionné comme candidat, et le 5, 10, 15, 20-tétrakis-meso-(4-carboxyphényl)porphyrineatozinc(II) (TCPP, avec Na+ comme contre-ion) a aussi été utilisé à des fins de comparaisons. TCPBP et TCPP ont, tous deux, été utilisés comme donneurs d’électrons pour fabriquer des assemblages supramoléculaires avec le cluster [Pd32+] comme accepteur d’électrons. Les calculs DFT ont été réalisés pour expliquer les structures de ces assemblages. Dans les conditions expérimentales, ces assemblages sont composés principalement d’une porphyrine avec 4 équivalents de clusters. Ces systèmes ont aussi été investigués par des mesures de quenching (perte de luminescence), par électrochimie et par d’autres techniques. Les transferts d’électrons (< 85 fs; temps inférieurs à la limite de détection) étaient aussi observés, de façon similaire aux assemblages MCP•••[Pd32+] et [Pd32+]•••DCP•••[Pd32+]. Les résultats nous indiquent que la modification de la structure de la porphyrine vers la tétrabenzoporphyrine ne semble pas influencer le comportement des cinétiques de transferts d’électrons (aller ou retour). Dans la troisième section, le chapitre 5, nous avons synthétisé la porphyrine hautement [pi]-conjuguée: 9, 18, 27, 36-tétra-(4-carboxyphényléthynyl)tétrabenzoporphyrinatozinc(II) (TCPEBP, avec Na+ comme contre-ion) par des fonctionnalisations en positions meso- et β, β-, qui présente un déplacement vers le rouge de la bande de Soret et des bandes Q. TCPEBP était utilisé comme donneur d’électrons pour fabriquer des motifs supramoléculaires avec le [Pd32+] comme accepteur d’électrons. Des expériences en parallèle ont été menées en utilisant la 5, 10, 15, 20-tétra-(4-carboxyphényl)éthynylporphyrinatozinc(II) (TCPEP, avec Na+ comme contre-ion). Des calculs DFT et TDDFT ont été réalisés pour de nouveau déterminer de façon théorique les structures de ces systèmes. Les constantes d’association pour les assemblages TCPEBP•••[Pd32+]x sont les plus élevées parmi tous les assemblages entre des porphyrines et le cluster de palladium rencontrés dans la littérature. La TAS a montré, encore une fois, des processus de transferts d’électrons dans des échelles de l’ordre de 75-110 fs. Cependant, les transferts de retour d’électrons sont aussi très rapides (< 1 ps), ce qui est un obstacle potentiel pour des applications en cellules solaires à pigment photosensible (DSSCs). Dans la quatrième section, le chapitre 6, les transferts d’énergie triplets (TET) ont été étudiés pour les assemblages MCP•••[Pd32+] et [Pd32+]•••DCP•••[Pd32+]. Les analyses spectrales des états transitoires dans l’échelle de temps de la ns-[mu]s démontrent de façon évidente les TETs; ceux-ci présentent des transferts d’énergie lents et/ou des vitesses moyennes pour des transferts d’énergie T1-T1 (3dye*•••[Pd32+] → dye•••3[Pd32+]*) opérant à travers exclusivement le mécanisme de Förster avec des valeurs de kET autour de ~ 1 × 105 s-1 selon les mesures d’absorption transitoires à 298 K. Des forces motrices non-favorables rendent ces types de processus non-opérants ou très lents dans les états T1. L’état T1 de [Pd32+] (~8190 cm-1) a été qualitativement déterminé par DFT et par la mise en évidence de l’émission S0 ← Tn retardée à 680-700 nm provenant de l’annihilation T1-T1, ce qui fait que ce cluster peut potentiellement agir comme un donneur à partir de ses états Tn, et accepteur à partir de T1 à l’intérieur de ces assemblages. Des pertes d’intensités de types statiques pour la phosphorescence dans le proche-IR sont observées à 785 nm. Ce travail démontre une efficacité modérée des colorants à base de porphyrines pour être impliquée dans des TETs avec des fragments organométalliques, et ce, même attachées grâce à des interactions ioniques. En conclusion, les assemblages ioniques à base de porphyrines et de clusters de palladium présentent des propriétés de transferts d’électrons S1 ultra-rapides, et des transferts d’énergie T1 de vitesses modérées, ce qui est utile pour de possibles applications comme outils optoélectroniques. D’autres études, plus en profondeur, sont présentement en progrès. / Abstract : Photoinduced electron and energy transfers play the pivotal role in various photochemical and photobiological redox processes including photosynthesis and respiration. Abundant covalently bonded systems have been designed to mimic the natural electron and energy transfer processes. However, the progress is often interfered by the difficulties to synthesize novel and versatile covalent donor-acceptor pairs. Recently, entities utilizing non-covalent interactions including hydrogen-bonding, [pi]-[pi] stacking, metal-ligand coordination and electrostatic interactions are becoming a hot topic since they are easy to be fabricated and tuned for selective and flexible electron and energy transfer behaviors. In this respect, the work presented in this thesis designed self-assemblies with porphyrins and a palladium cluster for photoinduced electron and energy transfers. It includes four main sections. In the first section, Chapter 3, two porphyrinic dyes, 5-(4-carboxylphenyl)-10, 15, 20-tristolyl(porphyrinato)zinc(II) (MCP, as sodium salt) and 5, 15-bis(4-carboxylphenyl)-15, 20-bistolyl(porphyrinato)zinc(II) (DCP, as sodium salt), were used as electron donors, and [Pd3(dppm)3(CO)]2+ ([Pd32+], dppm = (Ph2P)2CH2, as PF6‾ salt) cluster was adopted as the electron acceptor. The structure of [Pd32+]•••porphyrin assemblies was elucidated by geometry optimization using Density Functional Theory (DFT) calculations. Transient absorption spectroscopy (TAS) indicated a record fast electron transfer rate (< 85 fs, the time resolution limit) among the porphyrin-acceptor self-assemblies. Typically, these occur in ps-ns time scale. This rate is also comparable to the fastest electron transfer rate reported for the covalently linked porphyrin-acceptor systems (~ 50 fs, the time resolution limit). The ultrafast photo-induced electron transfers (ket > 1.2 × 1013 s-1) occurring at the S1 levels of the dyes in the structurally well-defined “straight up” ionic assemblies indicate that it is not necessary to have a strong bond and bent geometry between the donor and acceptor. In the second section, Chapter 4, we further studied the effect of using π-extended porphyrins on the electron transfer behavior of these assemblies. 9, 18, 27, 36-Tetrakis-meso-(4-carboxyphenyl)tetrabenzoporphyrinatozinc(II) (TCPBP, as a sodium salt) was selected as the candidate, and the 5, 10, 15, 20-tetrakis-meso-(4-carboxyphenyl)porphyrinatozinc(II) (TCPP, as a sodium salt) dye was also studied for comparison purposes. TCPBP and TCPP were both utilized as electron donors to fabricate supramolecular assemblies with the [Pd32+] cluster as the electron acceptor. DFT calculations were used to explain the structure of these assemblies. Under the experimental conditions used, these assemblies mainly exist in the form of one porphyrin with four equivalent clusters. These systems were also investigated by quenching measurements, electrochemistry, and other techniques. Ultrafast electron transfers (< 85 fs; time resolution limit) were also observed, which is similar as those for MCP•••[Pd32+] and [Pd32+]•••DCP•••[Pd32+] assemblies. The results indicate the structural modification from porphyrin to tetrabenzoporphyrin does not seemingly influence the kinetic behavior of the forward and back electron transfers. In the third section, Chapter 5, we synthesized a highly [pi]-conjugated porphyrin, 9, 18, 27, 36-tetra-(4-carboxyphenylethynyl)tetrabenzoporphyrinatozinc(II) (TCPEBP, as a sodium salt) by meso- and β, β-bifunctionalization, which exhibits large red shift of the Soret and Q-bands. TCPEBP was utilized as electron donors to fabricate supramolecular motifs with [Pd32+] cluster as the electron acceptor. Parallel experiments were conducted using 5, 10, 15, 20-tetra-(4-carboxyphenyl)ethynylporphyrinatozinc(II) (TCPEP, as a sodium salt). DFT and TDDFT calculations were applied to elucidate the structure of these assemblies. Binding constants for TCPEBP•••[Pd32+]x is the largest one among all the assemblies with porphyrin and palladium cluster. TAS showed again the ultrafast electron transfer process within the 75-110 fs time frame. However, the back electron transfers are also very fast (< 1 ps), which may be a potential obstacle for future applications in dye-sensitized solar cells (DSSCs). In the fourth section, Chapter 6, triplet energy transfers (TET) of the assemblies MCP•••[Pd32+] and [Pd32+]•••DCP•••[Pd32+] were studied. The transient spectral analysis in the ns-[mu]s time scale clearly demonstrates evidence for TET, which shows a slow to medium T1-T1 energy transfer (3dye*•••[Pd32+] → dye•••3[Pd32+]*) operating through a Förster mechanism exclusively with kET values of ~ 1 × 105 s-1 based on transient absorption measurements at 298 K. Unfavourable reductive and oxidative driving forces make this type of process inoperative or very slow in the T1 states. The T1 state of [Pd32+] (~8190 cm-1) has been quantitatively determined by DFT computations and by evidence for a delayed S0 ← Tn emission at 680-700 nm arising from T1-T1 annihilation, which makes this cluster potentially acting as the energy donor from its Tn state, and T1 acceptor within the assemblies. The static quenching of their near-IR phosphorescence at 785 nm was observed. This work demonstrated a moderate efficiency of the porphyrin dye to be involved in TET with an organometallic fragment, even when attached through ionic interactions. Conclusively, ionic assemblies with porphyrins and palladium clusters exhibit ultrafast S1 electron transfer and moderate T1 energy transfer properties, which is useful for possible application as optoelectronic devices. Further research in more depth is in progress.
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Síntese e caracterização de pentafluorofenil-piridil-porfirinas substituídas com complexos de rutênio / Synthesis and characterization of pentafluorophenil-pyridil-porphyrins substituted with ruthenium complex.

Moreira, Emmanuel Zimmermann 10 August 2007 (has links)
Esta dissertação apresenta a síntese, a caracterização de pentafluorofenil-piridilporfirinas base livre e substituídas com complexos de rutênio. Foi feita a investigação de como a inserção de grupos pentafluorofenil (grupos retiradores de elétrons) interfere nas das propriedades eletroquímicas, espectroscópicas e fotofísicas das porfirinas. A partir da coordenação do complexo [Ru(bpy)2Cl]+ e do cluster trinuclear de rutênio [Ru3O(Ac)6(py)2]+ à porfirina M(4-N-Py)TFPPH2 foram construídas as díades modelo [M(4-N-Py)TFFPH2{Ru3O(Ac)6(py)2}]PF6 e [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}] PF6, que foram caracterizadas pelas mesmas técnicas que as porfirinas. Também foram sintetizadas as tríades assimétricas cis- e trans-[B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2} {Ru(bpy)2Cl}](PF6)2, onde há a coordenação do complexo [Ru(bpy)2Cl]+ e do cluster trinuclear de rutênio [Ru3O(Ac)6(py)2]+ aos isômeros das porfirinas cis- e trans-B(4-N-Py)BFFPH2. Estas moléculas foram caracterizadas por análise de massa ESI MS e ESI MSMS e por espectroscopia UV-Vísivel. Pelos espectros UV-Vísivel pode-se notar que os espectros são apenas uma somatória do perfil espectral dos componentes, sugerindo ausên-cia de comunicação eletrônica. No entanto estudos eletroquímicos das díades [M(4-N-Py)TFFPH2{Ru3O(Ac)6(py)2}]PF6 e [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}]PF6 indicam que esta comunicação existe, embora pequena, não é negligenciável. Os estudos por análise de massa ESI MS e ESI MSMS foram realizados com as porfirinas, com o complexos [Ru(bpy)2Cl]+, com o cluster trinuclear de rutênio [Ru3O(Ac)6(py)2]+, com as díades modelos [M(4-N-Py)TFFPH2 {Ru3O(Ac)6(py)2}]PF6 e [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}]PF6 e com as tríades assimétricas cis- e trans-[B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2}{Ru(bpy)2Cl}](PF6)2. As estruturas dos compostos foram confirmados por ESI MS. Para as tríades cis- e trans-[B(4-N-Py)BFFPH2 {Ru3O(Ac)6(py)2}{Ru(bpy)2Cl}](PF6)2 os experimentos ESI MSMS permitiram verificar que a fragmentação dos compostos, levam às unidades monossubstituidas [B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2}]+ e [B(4-N-Py)BPFPH2{Ru(bpy)2Cl}]+ e os fragmentos substituintes [Ru(bpy)2Cl]+ e [Ru3O(Ac)6(py)2]+. Não foi possível verificar nenhuma diferença na fragmentação dos isômeros cis- e trans- das supermoléculas. Os ensaios de luminescência mostraram que a introdução de grupos modificadores [Ru(bpy)2Cl]+ e [Ru3O(Ac)6(py)2]+ suprimem a emissão da porfirina. Os dados fotofísicos preliminares mostram que as duas unidades ligadas às porfirinas M(4-N-Py)TFPPH2, cis- e trans- B(4-N-Py)BFPPH2 estão atuando como aceptor final de carga. / This work reports the synthesis and characterization of free base pentafluorophenylpyridilporphyrins as well as the synthesis and characterization of these compounds coordinated with ruthenium complexes. We have investigated how the insertion of pentafluorophenyl groups (electronwithdrawing groups) interferes with the eletrochemical, spectroscopic and photophysical properties of the compounds. The dyads models [M(4-N-Py)TFFPH2{Ru3O(Ac)6(py)2}]PF6 and [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}] PF6 were constructed using the [Ru(bpy)2Cl]+ complex, the trinuclear ruthenium cluster [Ru3O(Ac)6(py)2]+, and the free base porphyrin M(4-N-Py)TFPPH2. These dyads were characterized by the same techniques used to characterize the isolated porphyrins. The assimetric triads cis- and trans-[B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2} {Ru(bpy)2Cl}](PF6)2 were also synthesized, through coordination of the [Ru(bpy)2Cl]+ complex with the [Ru3O(Ac)6(py)2]+ trinuclear ruthenium complex and the cis- and trans isomers of the B(4-N-Py)BFFPH2 porphyrin. These molecules were characterized by ESI MS and ESI MSMS mass analyses and UV-Visible spectroscopy. The UV-Visible spectra were a sum of the spectral profile of the isolated components, suggesting a lack of eletronic communication between the units. However, electrochemical studies of the [M(4-N-Py)TFFPH2{Ru3O(Ac)6(py)2}]PF6 and [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}]PF6 dyads denoted this communication exists. So, despite being low, it must not be disregarded. ESI MS and ESI MSMS mass analyses of the porphyrins, the complex [Ru(bpy)2Cl]+, the trinuclear ruthenium cluster [Ru3O(Ac)6(py)2]+, the dyads model [M(4-N-Py)TFFPH2 {Ru3O(Ac)6(py)2}]PF6, and [M(4-N-Py)TFFPH2{Ru(bpy)2Cl}]PF6 and the assimetric triads cis- and trans-[B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2}{Ru(bpy)2Cl}](PF6)2 were carried out. The structures of the compounds were confirmed by ESI MS. The ESI MSMS experiments for the cis- and trans-[B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2} {Ru(bpy)2Cl}](PF6)2 triads allow us to verify that the fragmentation of the compounds results in the monosubstituted units [B(4-N-Py)BFFPH2{Ru3O(Ac)6(py)2}]+ and [B(4-N-Py)BPFPH2{Ru(bpy)2Cl}]+, and the substituents units [Ru(bpy)2Cl]+ and [Ru3O(Ac)6(py)2]+. No difference in the fragmentation of the cis- and trans-isomers of the supermolecules was detected. The luminescence experiments showed that the porphyrin emission is almost totally quenched because of the binding of the groups [Ru(bpy)2Cl]+ and [Ru3O(Ac)6(py)2]+. Photophysics results shows that these two units bounded to porhyrins M(4-N-Py)TFPPH2, cis- and trans- B(4-N-Py)BFPPH2 act as charge receptors.
60

Water soluble porphyrin based multichromophore arrays: assembled on G-Quadruplexes and silicon nanoparticle scaffolds

January 2013 (has links)
acase@tulane.edu

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