FLUORINATED ARENE, IMIDE AND UNSATURATED PYRROLIDINONE BASED DONOR ACCEPTOR CONJUGATED POLYMERS: SYNTHESIS, STRUCTURE-PROPERTY AND DEVICE STUDIES

Liyanage, Arawwawala Don T

01 January 2013

FLUORINATED ARENE, IMIDE AND LACTAM-FUNCTIONALIZED DONOR ACCEPTOR CONJUGATED POLYMERS: SYNTHESIS, STRUCTURE-PROPERTY AND DEVICE STUDIES After the discovery of doped polyacetylene, organic semiconductor materials are widely studied as high impending active components in consumer electronics. They have received substantial consideration due to their potential for structural tailoring, low cost, large area and mechanically flexible alternatives to common inorganic semiconductors. To acquire maximum use of these materials, it is essential to get a strong idea about their chemical and physical nature. Material chemist has an enormous role to play in this novel area, including development of efficient synthetic methodologies and control the molecular self-assembly and (opto)-electronic properties. The body of this thesis mainly focuses on the substituent effects: how different substituent’s affect the (opto)-electronic properties of the donor-acceptor (D-A) conjugated polymers. The main priority goes to understand, how different alkyl substituent effect to the polymer solubility, crystallinity, thermal properties (eg: glass transition temperature) and morphological order. Three classes of D-A systems were extensively studied in this work. The second chapter mainly focuses on the synthesis and structure-property study of fluorinated arene (TFB) base polymers. Here we used commercially available 1,4-dibromo-2,3,5,6-tetrafluorobenzene (TFB) as the acceptor material and prepare several polymers using 3,3’-dialkyl(3,3’-R2T2) or 3,3’-dialkoxy bithiophene (3,3’-RO2T2) units as electron donors. A detail study was done using 3,3’-bithiophene donor units incorporating branched alkoxy-functionalities by systematic variation of branching position and chain length. The study allowed disentangling the branching effects on (i) aggregation tendency, intermolecular arrangement, (iii) solid state optical energy gaps, and (iv) electronic properties in an overall consistent picture, which might guide future polymer synthesis towards optimized materials for opto-electronic applications. The third chapter mainly focused on the structure-property study of imide functionalized D-A polymers. Here we used thiophene-imide (TPD) as the acceptor moiety and prepare several D-A polymers by varying the donor units. When selecting the donor units, more priority goes to the fused ring systems. One main reason to use imide functionality is due to the, open position of the imide nitrogen, which provides an attaching position to alkyl substituent. Through this we can easily manipulate solubility and solid state packing arrangement. Also these imide acceptors have low-lying LUMOs due to their electron deficient nature and this will allow tuning the optical energy gap by careful choice of donor materials with different electron donating ability. The fourth chapter mainly contribute to the synthesis and structure property study of a completely novel electron acceptor moiety consist of a unsaturated pyrrolidinone unit known as Pechmann dye (PD) core. Pechmann dyes are closely related to the Indigo family. This can refer as 3-butenolide dimer connected via an alkene bridge, containing a benzene ring at the 5 and 5’ positions of the lactone rings. We have prepared several D-A polymers using this PD system with benzodithiophene (BDT) as the donor unit. Different to common D-A polymers the HOMO and LUMO of the PD acceptor moiety are energetically located within the gap of the BDT, so that the electronic and optical properties (HOMO-LUMO transition) are dictated by the PD properties. The promising electronic properties, band gaps, high absorption coefficients and broad absorption suggest this new D-A polymers as an interesting donor material for organic solar cell (OSC) applications.

Donor-Acceptor conjugated polymers

Organic Synthesis

Transition metal coupling

Organic semiconductors

Organic solar cell

Materials Chemistry

Organic Chemistry

Polymer Chemistry

Synthèse de nouveaux analogues de la Fosmidomycine : inhibiteurs potentiels de l'enzyme 1-Deoxy-D-Xylulose-5-Phosphate Reductoisomerase (DXR) / Targeting of the 1-Deoxy-D-Xylulose-5-Phosphate Reductoisomerase (DXR) enzyme : design and synthesis of new Fosmidomycin analogues as potential herbicides

Midrier, Camille

16 December 2010

La synthèse enzymatique de terpénoides chez les mammifères provient de la voie mevalonique. Récemment une voie différente a été découverte et s'est révélée être prépondérante pour de nombreux organismes comme les plantes et bactéries. L'identification d'un inhibiteur de cette cascade enzymatique permettrait le développement d'une nouvelle famille d'herbicide. Les caractéristiques de la 1-déoxy-D-xylulose 5-phosphate réductoisomérase (DXR) font de cette enzyme très spécifique une cible pour la synthèse de nouveaux composés. La Fosmidomycine ainsi que son analogue acétylé le plus proche, FR-900098 restent des références pour l'inhibition de la DXR. Dans ce contexte, l'ensemble des molécules décrites dans la littérature en tant qu'inhibiteurs a été classé en fonction des modifications apportées sur le substrat naturel ou la Fosmidomycine. A partir de l'ensemble de ces informations, cinq familles ont été synthétisées pour trouver un nouveau motif complexant. Pour deux d'entre elles, le squelette de base contient un acide phosphonique et un acide phosphinique sur lequel a été introduit la diversité moléculaire grâce aux réactions de Pudovik et de couplage pallado-catalysé. Les autres motifs complexant originaux sont constitués d'une fonction carbonyle et d'un hétérocycle en α ou β. Après optimisation de la synthèse des précurseurs, la diversité a été introduite à l'aide, par exemple, d'une réaction de trois composantes permettant la préparation d'hétérocycle. Enfin, deux modifications ont été faites sur le bras espaceur : l'introduction d'atomes de fluor pour modifier les propriétés physicochimiques ou d'un atome d'azote, point d'attache de nouveaux groupements. / The non-mevalonate pathway is widely found in higher plants and in many eubacteria, including pathogenic ones, but not in mammals. Identifying a non-mevalonate pathway inhibitor would greatly contribute to the search for new herbicides. The unique properties of 1-Deoxy-D-xylulose 5-phosphate reductoisomerase make it remarkable and rational target for drug design. The phosphonohydroxamic acid Fosmidomycin, which acts through inhibition of DXR, is a natural compound produced in the fermentation of Streptomyces and still remains, with its N-acetyl homologue FR900098, one of the most active compounds. First of all, the enzyme and all the potential inhibitors tested in literature were classified in order to understand the global quest for therapeutically useful compounds. In this context, we designed and synthesized five different families of Fosmidomycin analogues containing a new chelating unit. Two targets molecules families bearing a phosphinophonic acid as common core were imagined. Divergent approach allowed the introduction of the chemical diversity thank to powerful pallado-catalyzed coupling reaction. The other families containing carbonyl group and heterocycle in α‐ and β‐position were regarded as highly potent complexing units. Chemical diversity was introduced mainly at the end of the synthesis. For one of them convergent ring formation using three-components reaction was developed. Finally two modifications of the Fosmidomycin linker were performed by the introduction of fluorine atoms on the parent structure as well as the replacement of a carbon by a nitrogen atom in order to create a new point of modifications.

Herbicide

Fosmidomycine

Organophosphorés

Addition radicalaire

Couplage par les métaux de transition

Herbicide

Fosmidomycin

Organophosphorus compounds

Radical Chemistry

Transition metal coupling