Two-Photon Excited Fluorescence Depolarisation : Experimental and Theoretical Development

Ryderfors, Linus

January 2008

We have studied fundamental aspects of time-resolved two-photon excited fluorescence depolarisation. The thesis presents experimental as well as theoretical progress. We show that a multi-photon induced instrumental response function obtained from a suspension of gold nanoparticles is appropriate for the analysis of two-photon excited fluorescence decays obtained using time-correlated single photon counting detection. Theoretical expressions have been derived for the fluorescence anisotropy decay obtained upon two-photon excitation of various molecular systems in liquid solutions: a) an anisotropic rigid rotor that undergoes rotational diffusion in the presence of ultrafast unresolved restricted reorientations, e.g. librations. b) a molecular group covalently attached to a stationary macromolecule, and undergoing local reorientation in a uniaxial ordering potential. A new approach to the analysis of two-photon excited fluorescence depolarisation experiments was developed, which combines data obtained by using linearly and circularly polarised excitation light, in a global manner. In the analysis, knowledge about unresolved reorientations was obtained from one-photon excitation studies of the corresponding systems. By means of this procedure it has been possible to obtain quantitative information about the molecular two-photon absorption tensor for perylene and two of its derivatives. Thereby the symmetry of the final excited and intermediate vibronic states could be assigned. The analysis reveals that the two-photon transition studied with the 800 nm laser exhibits mixed character. An important finding from the experiments was that the two-photon absorption tensor appears to be solvent dependent. Furthermore, the thesis presents the first theoretical treatment of two-photon excited donor-donor energy migration in the presence of molecular reorientation and which applies the extended Förster theory. Explicit expressions for molecules that belong to the point groups D2h, D2 and C2v are given. Preliminary experiments are finally also reported on a two-photon excited donor-donor energy migration system consisting of a bisanthryl-bisteroid.

Two-photon excitation

Fluorescence

Fluorescence depolarisation

Fluorescence anisotropy

Time-correlated single photon counting

Gold nanoparticles

Rotational diffusion

Excited state symmetry

Extended Förster theory

Orientation correlation functions

Donor-donor energy migration (DDEM)

Chemical physics

Kemisk fysik

Molecular Quadratic Response Properties with Inclusion of Relativity

Henriksson, Johan

January 2008

This thesis concerns quadratic response properties and their application to properties in Jablonski diagrams such as resonant two-photon absorption and excited state absorption. Our main interest lies in optical power limiting applications, and in this context, molecules containing heavy metal atoms prove superior. Therefore, we are interested in how relativity affects these properties, and in order to assess this, a four-component relativistic framework is adopted. To properly address the molecular properties of interest, both relativistic effects and electron correlation need to be accounted for. These two properties are not additive, and, therefore, correlation needs to be incorporated into the four-component framework. We present the implementation of quadratic response properties at the four-component density functional level of theory. For second-harmonic generation, we have, with numerical examples, demonstrated that correlation and relativity are indeed not additive and that the inclusion of noncollinear magnetization is of little importance. We report that both electron correlation as well as relativity strongly affect results for second-harmonic generation. For example, relativity alone reduces the µβ-response signal by 62% and 75% for meta- and ortho-bromobenzene, respectively, and enhances the same response by 17% and 21% for meta- and ortho-iodobenzene, respectively. In the four-component framework, we present the implementations of single and double residues of the quadratic response function, which allows for the evaluation of resonant two-photon absorption cross sections and excited state properties. Using these tools, we discuss different levels of approximation to the relativistic Hamiltonian and we demonstrate that for two-photon absorption, a proper treatment of relativistic effects qualitatively alters the spectrum. For example, already for an element as light as neon, significant differences are seen between the relativistic and nonrelativistic spectra as triplet transitions acquire substantial absorption cross sections in the former case. Finally, quantum mechanics in conjunction with electrodynamics is applied to determine clamping levels in macroscopic samples. The microscopic properties of the optically active chromophores are determined by response theory, and then, electrodynamics is used to describe the interactions between the chromophores and incident laser pulses. Using this approach a series of molecules have been investigated and their performances have been compared and ranked in order to find novel materials for optical power limiting applications.

relativistic quantum chemistry

molecular physics

clamping levels

four-component Hartree-Fock theory

Kohn-Sham density functional theory

response theory

nonlinear optics

second-harmonic generation

two-photon absorption

excited state properties

optical power limiting

Computational physics

Beräkningsfysik

Core Level Spectroscopy of Water and Ice

Nordlund, Dennis

January 2004

A core level spectroscopy study of ice and water is presented in this thesis. Combining a number of experiments and spectrum calculations based on density functional theory, changes in the local valence electronic structure are shown to be sensitive to the local H-bonding configurations. Exploiting this sensitivity, we are able to approach important scientific problems for a number of aggregation states; liquid water, the water-metal interface, bulk and surface of hexagonal ice. For the H-bonded model system hexagonal ice, we have probed the occupied valence electronic structure by x-ray emission and x-ray photoelectron spectroscopy. Stepwise inclusion of different types of interactions within density functional theory, together with a local valence electron population analysis, show that it is essential to include intermolecular charge transfer together with internal s-p rehybridizations in order to describe the changes in electronic structure seen in the experiment. The attractive electrostatic interaction between water molecules is enhanced by a decrease in Pauli repulsion. A simple electrostatic model due to charge induction from the surrounding water is unable to explain the electronic structure changes. By varying the probing depth in x-ray absorption the structure of the bulk, subsurface and surface regions is probed in a thin ice film. A pronounced continuum for fully coordinated species in the bulk is in sharp contrast to the spectrum associated with a broken symmetry at the surface. In particular molecular arrangements of water with one uncoordinated OH group have unoccupied electronic states below the conduction band that are responsible for a strong anisotropic pre-edge intensity in the x-ray absorption spectrum. The topmost layer is dominated by an almost isotropic distribution of these species, which is inconsistent with an unrelaxed surface structure. For liquid water the x-ray absorption spectrum resembles that of the ice surface, indicating a domination of species with broken hydrogen bond configurations. The sensitivity to the local hydrogen bond configuration, in particular the sensitivity to broken bonds on the donor side, allows for a detailed analysis of the liquid water spectrum. Most molecules in liquid water are found in two-hydrogen-bonded configurations with one strong donor and one strong acceptor hydrogen bond. The results, consistent with diffraction data, imply that most molecules are arranged in strongly H-bonded chains or rings embedded in a disordered cluster network. Molecular dynamics simulations are unable to describe the experimental data. The water overlayer on the close-packed platinum surface is studied using a combination of core-level spectroscopy and density functional theory. A new structure for water adsorption on close-packed transition metal surfaces is found, where a weakly corrugated non-dissociated overlayer interacts via alternating oxygen-metal and hydrogen-metal bonds. The latter results from a balance between metal-hydrogen bond formation and OH bond weakening. The ultrashort core-hole lifetime of oxygen provides a powerful probe of excited state dynamics via studies of the non-radiative or radiative decay following x-ray absorption. Electrons excited into the pre-edge state for single donor species at the ice surface remain localized long enough for early time solvation dynamics to occur and these species are suggested as strong pre-existing traps to the hydrated electron. Fully coordinated molecules in the bulk contribute to a strong conduction band with electron transfer times below 0.5 femtoseconds. Upon core-ionization, both protons are found to migrate substantial distances on a femtosecond timescale. This unusually fast proton dynamics for non-resonant excitation is captured both by theory and experiment with a measurable isotope effect.

x-ray adsorption spectroscopy

photoemission spectroscopy

x-ray photoelectron spectroscopy

platinum

x-ray emission spectroscopy

density functional theory

hydrogen-bonded

H-bond

water

ice

electronic structure

excited state dynamics

proton dynamics

water adsorption

liquid water

Physics

Fysik

Propriedades ópticas não-lineares de oligômeros de anilina / Nonlinear optical properties of aniline oligomers

Paulo Licênio Franzen

29 October 2002

Apresentamos os resultados do estudo das não-linearidades ópticas de origem eletrônica de duas moléculas da classe dos oligômeros de anilina: o dímero e o tetrâmero. Foram medidas quatro concentrações de tetrâmero, puras e também dopadas em 33 e 100%; uma de dímero pura e outra dopada em 100%. As soluções foram preparadas usando dimetil-sulfóxido (DMSO) como solvente e a dopagem foi realizada com ácido clorídrico. As amostras foram caracterizadas por medidas de absorção linear e fluorescência antes das medidas não-lineares. Obtivemos os valores da primeira hiperpolarizabilidade (?) para todas as amostras, o índice de refração não-linear (n2) do tetrâmero dopado e não dopado, e a absorção não-linear em função da intensidade e da concentração do tetrâmero. As medidas foram realizadas através das técnicas de Varredura-Z, absorção não-linear e espalhamento Hiper-Rayleigh. Os resultados foram interpretados em termos da comparação entre diferentes estados de dopagem e da variação da seção de choque do estado fundamental para o primeiro excitado. / We report on the study of electronic optical non linearities in two aniline oligomers: dimer and the tetramer. Four tetramer concentrations were measured, pure and also 33 and 100% doped; one of dimer non doped another 100% doped. The solutions were prepared using dimethyl sulfoxide (DMSO) as solvent and the doping was performed with hydrochloric acid. The samples were characterized by measurements of linear absorption and fluorescence. We obtained the values of the first hyperpolarizability (?) for all samples, the non linear index of refraction (n2) for non doped and doped tetramer, and the non linear absorption in function of intensity and concentration of the tetramer. The measurements were accomplished through the techniques of Z-Scan, non linear absorption and Hyper-Rayleigh Scattering. The results were interpreted in terms of the comparison among different doping states and of the variation of cross-section for the transition from ground to the first excited states.

Absorção não linear

Dinâmica de estado exitado

Espalhamento hiper-Rayleigh

Fluorescência

Hiperpolarizabilidades

Oligômeros de anilina

Refração não linerar

Varredura-Z

Aniline oligomers

Excited state dynamics

Fluorescent decay time

Hiperpolarizabilities

Hyper-Rayleigh scatering

Nonlinear absorption

Nonlinear refraction

Z-scan

Ingénierie moléculaire pour l'optimisation des effets liés à l'absorption multiphotonique sur la famille Aza-Bodipy : application à la limitation optique aux fréquences des télécommunications / Molecular design of Aza-Bodipy dyes for multiphotonic absorption : towards optical limiting applications at telecommunication wavelengths

Bellier, Quentin

25 November 2011

La limitation optique (LO) est un processus de protection des détecteurs optiques (yeux, caméras…) vis-à-vis des agressions laser. Le développement rapide de ces derniers aux fréquences des télécommunications a encouragé l’ingénierie moléculaire pour la LO dans cette fenêtre spectrale, en particulier à 1500 nm. Un des principaux mécanismes de la LO est l’absorption multiphotonique et plus particulièrement l’absorption à deux photons (ADP). Il s’agit d’un phénomène d’optique non-linéaire du troisième ordre au cours duquel un électron est promu de l’état fondamental vers l’état excité par absorption simultanée de deux photons. De plus, des travaux récents ont mis en évidence que le phénomène de LO peut être exalté par des processus d’absorption à l’état excité (AEE) induits par ADP. Dans ce contexte, cette thèse décrit la synthèse d’une nouvelle famille de chromophores de type aza-dipyrrométhène de bore (Aza-Bodipy), fonctionnalisés par des groupements donneur ou accepteur d’électrons. Ces molécules ont un comportement de limiteur optique sur toute la gamme spectrale voulue, avec un maximum d’efficacité vers 1300 nm. Les résultats ont été interprétés sur la base de deux phénomènes : l’ADP, suivie de l’AEE pour un procédé d’absorption globale à trois photons. Ces deux processus ont été mesurés séparément et des relations structure-activité ont été établies, afin de rationnaliser les données de LO. L’importance du transfert de charge et la superposition spectrale des deux phénomènes sont alors apparues comme les paramètres clefs à optimiser. En vue d’une application dans un dispositif optique réel, il est nécessaire que les chromophores soient incorporés dans un matériau solide, qui peut être poli et transformé. Ainsi, les composés synthétisés ont été insérés avec succès dans une matrice sol-gel. Pour la première fois, des matériaux de qualité optique ont été réalisés, possédant des propriétés de LO dans l’infra-rouge très performantes et meilleures qu’en solution. / The optical power limiting (OPL) is a protection process of detectors (eyes, cameras…) against laser aggression. The rapid development of frequency-tunable pulsed lasers up to telecommunication wavelengths led to the design of new materials for nonlinear absorption in this spectral range, in particular at 1500 nm. Mutiphotonic absorption, such as the two-photon absorption (TPA) is one of the mechanisms involved in the OPL. TPA is a third order nonlinear phenomenon that promotes a molecule to an excited state by the simultaneous absorption of two photons. Moreover, the overall OPL efficiency can be enhanced by excited state absorption (ESA). In this context, this thesis describes the synthesis of a new family of versatile near infra-red dyes, namely aza-borondipyrromethene (Aza-Bodipy) featuring several sites of functionalization by electro-donating or electro-withdrawing moieties. These molecules present the typical behavior of optical limiters at telecommunication wavelengths, with a maximal efficiency around 1300 nm. OPL curves were interpreted on the basis of two phenomena: TPA, followed by ESA for an overall 2+1 photons absorption. These two processes have been measured independently and structure-activity relationships have been established in order to rationalize OPL experiments. The charge transfer effect and the spectral overlap between TPA and ESA are therefore the key parameters. For practical use of OPL functions, it is required for the chromophores to be introduced into a solid material, which enables polishing and other post-processing. Therefore, Aza-Bodipy dyes have been successfully incorporated to a solid matrix using the sol-gel technique. For the first time, optical quality materials have been prepared featuring OPL properties in the infra-red, which are better than the ones in solution.

Absorption à deux photons

Absorption à l’état excité

Limitation optique

Proche infra-rouge

Aza-dipyrrométhène de bore

Two-photon absorption

Excited state absorption

Optical limiting

Near infra-red dyes

Aza-borondipyrromethene

Nonlinear optics

Impact of Electronic State Mixing on the Photoisomerization Timescale of Natural and Synthetic Molecular Systems

Manathunga, Madushanka

26 November 2018

No description available.

Physical Chemistry

Biophysics

Organic Chemistry

Chemistry

Rhodopsin

Computational Chemistry

QM-MM

NAIP

Vibrational Coherence

Photochemistry

Photobiology

Excited State Lifetime

Photoreactivity

Franck-Condon Trajectory

Artificial Rhodopsin

Molecular Switch

Biomimetic

rPSB

Retinal Chromophore

Applying Fundamental Photochemistry to Drive Drug Development: The Photo-Dynamics and Reactions of Sulfur-Substituted Nucleic Acids

Pollum, Marvin

08 February 2017

No description available.

Chemistry

Molecules

Pharmaceuticals

Physical Chemistry

Quantum Physics

Analytical Chemistry

Biochemistry

Experiments

sulfur-substituted nucleobases

thiobases

photosensitizer

excited-state dynamics

femtosecond

intersystem crossing

triplet state

triplet yield

reactive oxygen species

singlet oxygen

photocrosslinking

photochemotherapy

photodynamic therapy

Zinc and ruthenium quinone diimine complexes: synthesis and photophysical properties

Dollberg, Christopher L.

17 February 2004

No description available.

Chemistry, Inorganic

Quinone Diimine Ligand

bqdi

nqdi

phi

Zinc

Ruthenium

Synthesis

Photochemistry

DNA Photocleavage

pH Dependence

Absorption

Emission

Photodynamic Therapy

Photo

Light Activation

Excited State

lifetime

Intra-Ligand-Charge-Transfer

ILCT

Ultrafast Time Resolved and Computational Studies of Diazo and Diazirine Excited States, and of Carbenes

Zhang, Yunlong

23 August 2010

No description available.

Chemistry

ultrafast

laser flash photolysis

vibrational spectroscopy

diazo

diazirine

excited state

carbene

computational study

calculations

ultrafast IR

ultrafast UV-Vis

phenylcarbene

S₁ state

photochemistry

Étude photophysique de nouveaux systèmes moléculaires fonctionnels basés sur les styrylpyridines

Marmois, Emilie

24 October 2008

Ce travail de thèse est principalement centré sur l’étude des processus photophysiques fondamentaux de nouveaux composés organiques à transfert de charge dérivés de styrylpyridine, réalisée grâce à des mesures de fluorescence résolue en temps à l’échelle picoseconde et d’absorption transitoire à l’échelle femtoseconde. Nous nous sommes tout d’abord intéressés au comportement des états excités de deux nouvelles hémicyanines. Les molécules de diméthoxystyrylpyridine méthylées ont montré l’établissement d’un équilibre entre les conformations syn et anti différent à l’état excité comparé à l’état fondamental, représenté par un temps de décroissance rapide de fluorescence. La deuxième constante de temps correspond à la dépopulation de l’état excité par les voies non radiatives telles que l’isomérisation et le twist du donneur de charge (effet « loose-bolt »). Concernant le dérivé de styrylpyridinium où le groupement phényl a été remplacé par diméthlaminothiophene, nos études ont prouvé l’implication du mouvement de rotation du groupement méthylpyridinium ainsi que l’intervention du croisement inter-système comme voies de relaxation. Dans un second temps, nous nous sommes penchés sur les propriétés de complexation de la molécule de styrylpyridine sur laquelle a été substitué un éther-couronne. Nos études nous ont permis de mettre en évidence la présence de deux centres de complexation (un au centre de la couronne, l’autre sur l’azote de la pyridine) montrant une sélectivité différente vis-à-vis des cations métalliques. Les stoechiométries ont pu être confirmées par une analyse des temps de réorientation des complexes formés. Après avoir étudié les divers composés constituant des « briques » élémentaires en vue de systèmes supramoléculaires plus élaborés, nous nous sommes intéressés à leurs éventuelles applications avec l’étude de systèmes pour la collecte et le transfert d’énergie. Nous avons tout d’abord démontré l’existence d’un transfert d’énergie ultra-rapide (180 fs à 6 ps) et ultra-efficace (>99.7%) dans des systèmes bichromophoriques contenant deux styrylpyridines avec un éther-couronne et asymétrisés par l’introduction d’un cation Mg2+ dans une seule couronne. Celui-ci se fait de la partie complexée vers la partie non complexée par interaction coulombienne. Une autre application envisagée réside dans la construction de complexes à métaux de transition pour le stockage d’énergie ou le stockage d’information. Nous avons tout d’abord étudié la formation d’un système supramoléculaire basé sur le phénanthroline et contenant quatre éther-couronnes libres. Nous avons mis en évidence l’existence d’un équilibre entre états singulets et triplets excités dans ces composés complexés avec Cuivre(I) ou Argent(I). Dans un second temps, nous avons étudié la formation de complexes liant deux bipyridines substitués contenant un éther-couronne à un ion Fe2+. Un tel complexe présente des propriétés de transition de spin BS?HS. Nos études ont ensuite révélé la formation de complexes à métaux de transition de taille nanométrique lors de l’ajout d’ions Ba2+. / This Ph.D. work mainly deals with the study of fundamental photophysical processes of new styrylpyridine-type organic compounds showing charge transfer, realised using picosecond fluorescence and femtosecond transient absorption. We were interested first in the excited-state behaviour of two new hemicyanines. Methylated dimethoxystyrylpyridines molecules showed the establishment of an equilibrium between syn and anti conformations which is different in the excited state compared to the ground state, represented by a fast relaxation time of fluorescence. The second time constant corresponds to depopulation of the the excited state by non-radiative pathways as isomerization and donor twist (« loose-bolt »). Concerning styrylpyridinium derivative where phenyl group was replaced by dimethylaminothiophene, our studies proved involvment of rotation of methylpyridinium group and intersystem crossing as relaxation pathways. Secondly, we were interested in complexation properties of ether-crown susbstituted styrylpyridine molecule. Our studies showed the presence of two complexation centers (one in the center of the crown, the other one on the nitrogen of pyridine) having a different selectivity for metallic cations. Stoichiometries were confirmed by analysis of the reorientation times of formed complexes. After the study of our different compounds as elementary « building–blocks » for more complex supramolecular systems, we were interested in their potential applications with the study of systems for collection and energy transfer. First, we highlighted the existence of an ultra fast (180 fs to 6 ps) and ultra efficient (>99.7%) intramolecular energy transfer in bichromophoric systems containing two ether-crowned styrylpyridines and dissymetrised by binding of a Mg2+ cation in only one crown. It occurs from the complexed part to the non-complexed one by coulombic interaction. Another envisaged application can be the construction of complexes containing transition metals for energy or information storage. We studied first the building of a supramolecular system based on phenanthroline and containing four free ether-crowns We also proved that there exists an equilibrium between singlet and triplet excited states in these compounds complexed with Copper(I) or Silver(I). Secondly, we studied formation of complexes binding two ether-crown substituted bipyridines to a Fe2+ ion. Such a complex has got some spin crossover properties. Then, we showed that the addition of Ba2+ ions induce formation of transition metals complexes with nanometric size.

Styrylpyridine

Transfert de charge

Fluorescence résolue en temps

Absorption transitoire

Photodynamique des états excités

Conversion interne

Croisement inter-système

États twistés

Complexes organo-métalliques

Transfert d’énergie

Métaux de transition

Transition de spin

Styrylpyridine

Charge transfer

Time-resolved fluorescence

Transient absorption

Excited-state photodynamics

Internal conversion

Inter-system crossing

Twisted states

Organo-metallic complexes

Energy transfer

Transition metals

Spin crossover