Exploring copper(I) and ruthenium(II) dyes for their use in dye-sensitised solar cells

Hewat, Tracy Elizabeth

January 2013

Dye design is one of the most important and challenging areas in dye-sensitised solar cell research. The purpose of the work in this thesis is to synthesise and characterise novel ruthenium(II) and copper(I) dyes that will provide insight into the number of binding groups required and the potential use of chromophoric ligands. A series of four simple Ru(II) dyes have been synthesised with the general formula Ru(4,4’- (R)-bipyridine)2(NCS)2 where R represents CH3 or CO2H. The study investigates the number of acid groups required to successfully bind to TiO2 whilst maintaining efficient charge injection. The series consists of one acid group, two acids, two acids on adjacent bipyridines, and three acids groups. Dye uptake was studied via optical waveguide spectroscopy, providing information on dye diffusion, adsorption and desorption kinetics, and surface coverage. Interestingly, the two acid groups on adjacent ligands suggested poor/slow binding to TiO2 surface and a high degree of dye aggregation in comparison to two acid groups on the same ligand. The dye with three binding groups showed strong adsorption to TiO2 and better dye coverage, resulting in a high efficiency. The complexes were all fully characterised by electrochemistry, photoluminescence, absorption spectroscopy, DFT calculations and solar cell performance testing. To date, there has been limited exploration of copper(I) complexes as potential alternatives to ruthenium(II) sensitisers, with even fewer publications reported for Cu(I) heteroleptic species. The neutral complexes that were synthesised are of the general formula: Cu(4,4’- (R)-6,6’-(CH3)-bipyridine)(β-diketonate) and Cu(4,4’-(R)-6,6’-(CH3)-bipyridine)(dipyrrin) where R represents CH3 or CO2Et. Additional blocking groups on the ligands are introduced to minimise structural change during oxidation or MLCT excitation. Improved stability and reproducibility have been shown for complexes containing the dipyrrin ligand, likely due to better steric constraints and better π-overlap with the bipyridine. There has also been a remarkable improvement in light absorption, from 450 nm to 600 nm. In-situ solar studies have been carried out on the Cu(4,4’-(R)-6,6’-(CH3)-bipyridine)(dipyrrin) series and a 0.41% efficiency has been achieved. Computational studies supports the experimental data in which the main transition appears to be ligand centred (dipyrrin) with a small MLCT contribution.

621.31

Charge Distribution in the MLCT States of <i>trans</i>-M₂L₂L’₂ and M₂L₄ Compounds Studied by Femtosecond Spectroscopy, where M= Mo and W

Jiang, Changcheng

January 2016

No description available.

Chemistry

Photophysics and Excited State Electronic Communication in Quadruply Bonded Paddlewheel Complexes of Molybdenum and Tungsten

Alberding, Brian

12 September 2011

No description available.

Chemistry

quadruple bond

transient absorption spectroscopy

time-resolved infrared spectroscopy

MLCT state

delta-delta star state

electronic communication

singlet

triplet

Discovering the Potential of Photoluminescent Ruthenium(II) Complexes as Photodynamic Therapy Agents

Padilla, Roberto

02 March 2016

Anthracene was attached to light activated, ruthenium-based DNA disruptors to probe their distribution in cancer cells. The objective of this research is to understand the photophysical properties (Chapter 2), photoreactivity toward DNA and proteins (Chapter 3), and localization within cancer cells (Chapter 4) of ruthenium complexes that demonstrate promise as photodynamic therapy (PDT) agents. [(AnthbpyMe)(bpy)Ru(dpp)]2+ (1) and [(AnthbpyMe)2Ru(dpp)]2+ (2) absorb visible light with metal-to-ligand charge transfer (MLCT) transitions at 459 nm (16,000 M-1 cm-1 ) and 461 nm (21,000 M-1 cm-1 ), respectively. These species exhibit 3 MLCT emissions at λem = 661 nm and λem = 663 nm for 1 and 2, respectively, while the anthracene show emissions at 450 – 560 nm. The anthracene unit(s) quench the 3 MLCT to give quantum yields (lifetime) of Φem = 0.0059 [398(1) ns] and Φem = 0.0011 [414(1) ns] for 1 and 2, respectively. Voltammetry shows an irreversible anthracene oxidation at 1.23 – 1.28 V, RuIII/II oxidation at 1.53 – 1.55 V, and quasi-reversible reduction couples attributed to dpp0/-1 at 0.98 V. DNA gel shift assays demonstrate that complexes 1 and 2 modify DNA in the presence and absence of 3 O2 upon light activation to convert supercoiled DNA to a mixture of open circular (OC) DNA and a species that exhibit sa distinctly different migration rate than either OC and linear DNA. Binding constants, Kb, for complexes 1 and 2, toward DNA are 3.50 × 105 (3.50 × 104 ) and 4.50 × 103 (4.50 × 102 ) respectively. SDS-PAGE assays show that the complexes 1 and 2 modify bovine serum albumin (BSA) through an 3 O2-dependent mechanism upon light iii activation. The localization and PDT potency of the anthracene-Ru-dpp complexes are tested against F98 cells, which are rat glioma cells that simulate the infiltrative patterns of growth in cancer. Confocal microscopy demonstrates that complexes 1 and 2 internalize and localize primarily along the cell membrane and associate with dot-like vesicles within the cytoplasm. Complexes 1 and 2 show IC50 values of 107 µM and 85 µM, respectively, after 15 min of drug exposure and 1 h of PDT-treatment (λPDT = 455 nm). / Ph. D.

Anthracene

photodynamic therapy

supramolecular complexes

subcellular localization

cytotoxicity

phototoxicity

DNA

protein

malignant glioma

ruthenium

MLCT

gel shift assay

confocal microscopy

Monomeric, Dimeric and Polymeric Re^I(CO)₃ Schiff Base Complexes: Synthetic, Spectroscopic, Electrochemical, and Computational Studies

Hasheminasab, S. Abed

09 June 2016

No description available.

Chemistry

MLCT

mixed valence

main chain organometallic polymers

photovoltaic

HOMO

LUMO

DFT

TDDFT

cyclic voltametry

AFM

SEM

comproportionation constant

Yamamoto coupling

Heck coupling

Schiff base

time-resolved pectroscopy

Propriétés photo-physiques de nouveaux matériaux moléculaires pour la conversion de photons en énergie / Photo-physical proprieties of new molecular materials for light-to-energy conversion

Liu, Li

14 June 2017

Plusieurs processus photo-induits d'énergie et de transfert d'énergie ont été étudiés en solution et dans le film par spectroscopie d'absorption transitoire et de fluorescence pour deux types de cellules solaires. Combinés avec d'autres expériences et par une analyse globale, ces phénomènes ultrarapides avec leur durée de vie ont été observés et les scénarios photo-induits ont été déterminés. La compréhension approfondie des matériaux moléculaires pourrait aider les chimistes à concevoir des cellules solaires efficaces. La première étude sur l'influence des conceptions chimiques sur la formation et la séparation des charges implique différentes fractions donneuses et différents solvants et les résultats ont été expliqués par la théorie de Marcus-Jortner combinée avec le calcul quantique. La deuxième étude porte sur les complexes Fe (II) comme photosensibilisateurs pour les cellules solaires sensibilisées aux colorants. On a étudié une série de complexes de Fe (II) homo et hétérotéptiques avec des ligands de carbène et de terpyridine en solution et dans le film. La durée de vie de l'état de transfert de la charge métal-ligand du triplet d'enregistrement du complexe Fe (II) est obtenue en solution. La compréhension du film est en cours. / Various photo-induced energy and energy transfer processes were investigated in solution and in the film by transient absorption and fluorescence spectroscopies for two types of solar cells. Combined with other experiments and through a global analysis, those ultrafast phenomena with their lifetimes were observed and the photo-induced scenarios were determined. The insight understanding of molecular materials could help chemists to design efficient solar cells.The first study about the influence of chemical designs on charge formation and separation involves different donor moieties and different solvents and the results were explained by Marcus-Jortner theory combined with quantum calculationThe second investigation is about Fe(II) complexes as photosensitizers for dye-sensitized solar cells. A series of homo- and heteroleptic Fe(II) complexes with carbene and terpyridine ligands have been studied in solution and in the film. The record triplet metal-to-ligand charge transfer state lifetime of Fe(II) complex is achieved in solution. The further understanding in the film is in progress.

Spectroscopie ultra-rapide

Cellules solaires

Transfert d’énergie et de charge

Complexe de fer

Optique non linéaire

Ultrafast transient spectroscopies

Solar cells

Energy and charge transfer

CT state

MLCT state

Iron complex

Nonlinear optics

541.3