Prediction Of Optical Properties Of Pi-conjugated Organic Materials For Technological Innovations

Nayyar, Iffat

01 January 2013

Organic π-conjugated solids are promising candidates for new optoelectronic materials. The large body of evidence points at their advantageous properties such as high charge-carrier mobility, large nonlinear polarizability, mechanical flexibility, simple and low cost fabrication and superior luminescence. They can be used as nonlinear optical (NLO) materials with large two-photon absorption (2PA) and as electronic components capable of generating nonlinear neutral (excitonic) and charged (polaronic) excitations. In this work, we investigate the appropriate theoretical methods used for the (a) prediction of 2PA properties for rational design of organic materials with improved NLO properties, and (b) understanding of the essential electronic excitations controlling the energy-transfer and charge-transport properties in organic optoelectronics. Accurate prediction of these electro-optical properties is helpful for structureactivity relationships useful for technological innovations. In Chapter 1 we emphasize on the potential use of the organic materials for these two applications. The 2PA process is advantageous over one-photon absorption for deep-tissue fluorescence microscopy, photodynamic therapy, microfabrication and optical data storage owing to the three-dimensional spatial selectivity and improved penetration depth in the absorbing or scattering media. The design of the NLO materials with large 2PA cross-sections may reduce the optical damage due to the use of the high intensity laser beams for excitation. The organic molecules also possess self-localized excited states which can decay radiatively or nonradiatively to form excitonic states. This suggests the use of these materials in the electroluminescent devices such as light-emitting diodes and photovoltaic cells through the processes of exciton formation or dissociation, respectively. It is therefore necessary to understand ultrafast relaxation processes required in understanding the interplay between the iv efficient radiative transfer between the excited states and exciton dissociation into polarons for improving the efficiency of these devices. In Chapter 2, we provide the detailed description of the various theoretical methods applied for the prediction as well as the interpretation of the optical properties of a special class of substituted PPV [poly (p-phenylene vinylene)] oligomers. In Chapter 3, we report the accuracy of different second and third order time dependent density functional theory (TD-DFT) formalisms in prediction of the 2PA spectra compared to the experimental measurements for donor-acceptor PPV derivatives. We recommend a posteriori Tamm-Dancoff approximation method for both qualitative and quantitative analysis of 2PA properties. Whereas, Agren's quadratic response methods lack the double excitations and are not suitable for the qualitative analysis of the state-specific contributions distorting the overall quality of the 2PA predictions. We trace the reasons to the artifactual excited states above the ionization threshold. We also study the effect of the basis set, geometrical constraints and the orbital exchange fraction on the 2PA excitation energies and cross-sections. Higher exchange (BMK and M05-2X) and range-separated (CAM-B3LYP) hybrid functionals are found to yield inaccurate predictions both quantitatively and qualitatively. The failure of the exchangecorrelation (XC) functionals with correct asymptotic is traced to the inaccurate transition dipoles between the valence states, where functionals with low HF exchange succeed. In Chapter 4, we test the performance of different semiempirical wavefunction theory methods for the prediction of 2PA properties compared to the DFT results for the same set of molecules. The spectroscopic parameterized (ZINDO/S) method is relatively better than the general purpose parameterized (PM6) method but the accuracy is trailing behind the DFT methods. The poor performances of PM6 and ZINDO/S methods are attributed to the incorrect description of excited-to-excited state transition and 2PA energies, respectively. The different v semiempirical parameterizations can at best be used for quantitative analysis of the 2PA properties. The ZINDO/S method combined with different orders of multi-reference configuration interactions provide an improved description of 2PA properties. However, the results are observed to be highly dependent on the specific choice for the active space, order of excitation and reference configurations. In Chapter 5, we present a linear response TD-DFT study to benchmark the ability of existing functional models to describe the extent of self-trapped neutral and charged excitations in PPV and its derivative MEH-PPV considered in their trans-isomeric forms. The electronic excitations in question include the lowest singlet (S1) and triplet (T1 † ) excitons, positive (P+ ) and negative (P- ) polarons and the lowest triplet (T1) states. Use of the long-range-corrected DFT functional, such as LC-wPBE, is found to be crucial in order to predict the physically correct spatial localization of all the electronic excitations in agreement with experiment. The inclusion of polarizable dielectric environment play an important role for the charged states. The particlehole symmetry is preserved for both the polymers in trans geometries. These studies indicate two distinct origins leading to self-localization of electronic excitations. Firstly, distortion of molecular geometry may create a spatially localized potential energy well where the state wavefunction self-traps. Secondly, even in the absence of geometric and vibrational dynamics, the excitation may become spatially confined due to energy stabilization caused by polarization effects from surrounding dielectric medium. In Chapter 6, we aim to separate these two fundamental sources of spatial localization. We observe the electronic localization of P + and Pis determined by the polarization effects of the surrounding media and the character of the DFT functional. In contrast, the self-trapping of the electronic wavefunctions of S1 and T1(T1 † ) mostly follows their lattice distortions. Geometry vi relaxation plays an important role in the localization of the S1 and T1 † excitons owing to the nonvariational construction of the excited state wavefunction. While, mean-field calculated P + , Pand T1 states are always spatially localized even in ground state S0 geometry. Polaron P+ and Pformation is signified by the presence of the localized states for the hole or the electron deep inside the HOMO-LUMO gap of the oligomer as a result of the orbital stabilization at the LCwPBE level. The broadening of the HOMO-LUMO band gap for the T1 exciton compared to the charged states is associated with the inverted bond length alternation observed at this level. The molecular orbital energetics are investigated to identify the relationships between state localization and the corresponding orbital structure. In Chapter 7, we investigate the effect of various conformational defects of trans and cis nature on the energetics and localization of the charged P + and Pexcitations in PPV and MEHPPV. We observe that the extent of self-trapping for P+ and Ppolarons is highly sensitive on molecular and structural conformations, and distribution of atomic charges within the polymers. The particle-hole symmetry is broken with the introduction of trans defects and inclusion of the polarizable environment in consistent with experiment. The differences in the behavior of PPV and MEH-PPV is rationalized based on their orbital energetics and atomic charge distributions. We show these isomeric defects influence the behavior and drift mobilities of the charge carriers in substituted PPVs.

Oraganic conjugated polymers

optoelectronic applications

two photon absorption

non linear optical properties

time dependent density functional theory

excited state dynamics

charge transport

polarons

excitons

exchange correlation functionals

Physics

Spectroscopic Investigation of the Excited State Properties of Platinum(Ii) Charge Transfer Chromophores

Glik, Elena A.

25 November 2009

No description available.

Chemistry

platinum

platinum acetylides

photophysical properties

spectroelectrochemistry

transient absorption

time-resolved IR

excited state dynamics

charge transfer

electron transfer

energy transfer

OPTICAL PROPERTIES AND POPULATION STATISTICS OF ERBIUM IN OPTICALLY-PUMPED ERBIUM-DOPED ZINC SILICATE GERMANATE WAVEGUIDE AMPLIFIERS

BANERJEE, SIDDHARTHA

January 2004

No description available.

Erbium doped waveguide amplifiers

absorption and emission cross-sections

population statistics

gain dynamics

Erbium excited state life-time

facet reflectivity

waveguide scattering loss

optically pumped lasing

Computational And Experimental Studies Towards The Development Of Novel Therapeutics Against Organophosphorus Nerve Agents: Butyrylcholinesterase And Paraoxonase

Vyas, Shubham

12 September 2011

No description available.

Chemistry

Physical Chemistry

Organophosphorus Compounds

Butyrylcholinesterase

Acetylcholinesterase

Pyridinium Oxime

Paraoxonase-1

Excited State

Phosphoryl Azide

Phosphorylnitrene

DFT Calculations

RI-CC2 Calculations

Molecular Dynamics

Molecular Docking

A Comprehensive Investigation of Photoinduced Electron Transfer and Charge Transfer Mechanisms in Push-Pull Donor-Acceptor Systems: Implications for Energy Harvesting Applications

Alsaleh, Ajyal Zaki

12 1900

Donor-acceptor systems exhibit distinctive attributes rendering them highly promising for the emulation of natural photosynthesis and the efficient capture of solar energy. This dissertation is primarily devoted to the investigation of these unique features within diverse donor-acceptor system typologies, encompassing categories such as closely covalently linked, push-pull, supramolecular, and multi-modular donor- acceptor conjugates. The research encompasses an examination of photosynthetic analogs involving compounds such as chelated azadipyromethene (AzaBODIPY), N,N-dimethylaminophenyl (NND), phenothiazine (PTZ), triphenylamine (TPA), phenothiazine sulfone (PTZSO2), tetracyanobutadiene (TCBD), and expanded tetracyanobutadiene (exTCBD). The strategic configuration of the donor (D), acceptor (A), and spacer elements within these constructs serves to promote intramolecular charge transfer (ICT), which are crucial for efficient charge and electron transfer. The employment of cutting-edge analytical techniques, such as ultrafast transient absorption spectroscopy, is integral to the study. Furthermore, a comprehensive suite of analytical methodologies including steady-state UV-visible absorption spectroscopy, fluorescence and phosphorescence spectroscopies, electrochemical techniques (including cyclic voltammetry and differential pulse voltammetry), spectroelectrochemistry, and density functional theory calculation (DFT), collectively contribute to the comprehensive characterization of push-pull donor-acceptor systems, with a particular emphasis on their potential as highly effective solar energy harvesting application.

Ultrafast spectroscopy

excited-state charge separation

azaBODIPY

Charge transfer

push-pull systems

donor-acceptor constructs

Tetracyanobutadiene (TCBD)

and phenothiazine

Chemistry, Analytical

Chemistry, Physical

Chemistry, Organic

New Polyazine-Bridged Ru(II),Rh(III) and Ru(II),Rh(I) Supramolecular Photocatalysts for Water Reduction to Hydrogen Applicable for Solar Energy Conversion and Mechanistic Investigation of the Photocatalytic Cycle

Zhou, Rongwei

09 November 2014

The goal of this research is to test the design constraints of active dpp-bridged RuII,RhIII (dpp = 2,3-bis(2-pyridyl)pyrazine)) supramolecular photocatalysts for water reduction to H2 and provide mechanistic insights into the catalytic cycle. Two member of a new RuII,RhIII motifs with only one Rh-'Cl bond, [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 ( bpy = 2,2'-bipyridine, tpy = 2,2':6,2"-terpyridine) and [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4, (tpm = tris(1-pyrazolyl)methane), and a cis-RhCl2 model system, [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3, were prepared. This new motif was to test whether two Rh-'Cl bonds on RhIII are required for the photocatalytic water reduction. 1H NMR spectroscopic analysis of complexes prepared using deuterated ligands was used to characterize these three RuII,RhIII supramolecular complexes. Electrochemical studies suggested that replacing bpy with a tridentate ligand on RhIII shifts the RhIII/II and RhII/I reduction couples positively, which can modulate the orbital energetics of the RhIII LUMO (lowest-unoccupied molecular orbital). This substitute also changes the rate of ligand dissociation following the reduction of RhIII. In tpm and bpy systems, RhII intermediate is more stable than that in the tpy system. All three complexes were good light absorbers in the visible region and weak emitters from their emissive Ru(dπ)-'dpp(π*) 3MLCT (metal-to-ligand charge transfer) excited states at room temperature. The population of a low-lying 3MMCT (metal-to-metal charge transfer) ES (excited state) from the 3MLCT ES contributed to the weak emission, indicating an important intramolecular electron transfer process from dpp' to RhIII upon photoexcitation. The lower-lying 3MMCT excited state in the tpm and tpy systems relative to the bpy system result in a higher rate constant (ket = 2.6 x 10^7 vs 1.7 x 10^7 s-1) for intramolecular electron transfer. Spectrophotochemical analysis suggested that all three complexes were photoinitiated electron collectors capable of collecting two electrons on the RhIII center to generate the RuII,RhI species in the presence of DMA (N,N-dimethylaniline). The observed H2 production from water using [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4 and [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 established that two halides on RhIII are not necessary in the dpp-bridge RuII,RhIII supramolecular photocatalytic-water-reduction system. This new discovery opens a new approach to the design of different RuII,RhIII motifs for photocatalysis. The active species for water reduction is proposed to be [(bpy)2Ru(dpp)RhICl(TL)]3+ from [(bpy)2Ru(dpp)RhCl(TL)](PF6)4 (TL (terminal ligand) = tpy or tpm) and [(bpy)2Ru(dpp)Rh(bpy)]3+ from [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3 respectively. Included here is the design and study of a RuII,RhI complex, [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 (COD =1,5-cyclooctadiene) to provide more insights into the photophysical and photochemical properties of polypyridyl RuII,RhI species. Electrochemical and photophysical studies revealed a dpp-based LUMO in this RuII,RhI complex, suggesting dpp reduction upon photoexcitation. Photochemical study found that [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 is an active photocatalyst for water reduction and that additional reduction(s) is (are) required after the generation of the RuII,RhI active species in the RuII,RhIII supramolecular photocatalytic H2 production system. This hypothesis was supported by the electrocatalytic behaviors of the RuII,RhIII supramolecular complexes for proton reduction. Cyclic voltammetry results in the presence of an acid suggested that the protonolysis of the RuII,RhIIH and RuII,RhIH species are electrocatalytic H2-evolution pathways. The mechanism is acid-dependent and influenced by terminal ligand. The studies of electrocatalytic proton reduction on these RuII,RhIII complexes suggested several possible intermediates involved in the photocatalytic water reduction cycle. The insights gained from this research can provide guidance in designing new type of RuII,RhIII and RuII,RhI complexes with better photocatalytic and/or electrocatalytic H2 production performance. / Ph. D.

supramolecular complexes

solar energy

water splitting

hydrogen production

tridentate ligand

rate constant

halide loss

photoinitiated electron collector

excited state quenching

photocatalysis

electrocatalysis

protonation

protonolysis

rhod

Two-Photon Excited Fluorescence Depolarisation : Experimental and Theoretical Development

Ryderfors, Linus

January 2008

<p>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 D_2h, D₂ and C_2v are given. Preliminary experiments are finally also reported on a two-photon excited donor-donor energy migration system consisting of a bisanthryl-bisteroid. </p>

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

Anabaena Sensory Rhodopsin : effect of mutations on the ultrafast photo-isomerization dynamics / Anabena sensory rhodospin : l'impact de mutations sur la dynamique ultra-rapide de la photo-isomerization

Agathangelou, Damianos

14 January 2019

ASR, est une protéine photo réceptrice qui lie la base protonée de la rétine de Schiff dans deux conformations de l'état fondamental. La protéine particulière consiste en un système modèle dans lequel I'effet de l'environnement protéique sur la dynamique d'isomérisation des deux isomères peut être étudié. Dans cette thèse, une étude approfondie sur les protéines mutées ponctuellement est présentée, où la variable est l'environnement protéique. Les résultats montrent des différences significatives entre les durées de vie des états excités des deux isomères et les durées de vie plus courtes ou plus longues commentées en termes de mélange électronique Sl/S2. En complément, le développement expérimental d'un spectromètre à absorption transitoire (T.A) et d'un dispositif de spectroscopie électronique bidimensionnelle (2DES) fonctionnant respectivement dans les domaines spectral NIR et UV-Vis. Avec cette configuration, deux impulsions colinéaires à verrouillage de phase d'une durée inférieure à 10fs sont générées, où. la précision interférométrique sur le contrôle du retard entre les deux impulsions de pompe permet d'effectuer des mesures 2DES. / ASR, is a photoreceptor protein that binds the protonated Schiff base of retinal in two ground state conformations. The particular protein consists a model system where the effect of the protein environment on the isomerization dynamics of the two isomers can be investigated. In this thesis an extended study on point mutated proteins is presented where the variable is the protein environment. The results show significant differences between the two isomers excited state lifetimes with the shorter or longer lifetimes commented in terms of Sl/S2 electronic mixing. Supplementary, the experimental development of a Transient absorption spectrometer (T.A) and a Two-dimensional electronic spectroscopy setup (2DES) operating in the NIR and UV-Vis spectral range respectively are described. The 2DES spectrometer is based on translating wedges made out of birefringent material producing two collinear phase-locked pulses with sub-I Ofs duration. The interferometric precision on controlling the delay between the two pump pulses allows to perform 2DES measurements on systems absorbing in the 360-430 nm range allowing to resolve the excitation process spectrally.

Isomérisation

Mutations

Durée de vie excitée

Protéines

Modes de vibration

Spectroscopie d'absorption transitoire

Lasers

Isomerization

Mutations

Excited state lifetime

Proteins

Vibrational modes

Transient absorption spectroscopy

Two dimensional electronic spectroscopy

Lasers

547.7

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

Franzen, Paulo Licênio

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

Aniline oligomers

Dinâmica de estado exitado

Espalhamento hiper-Rayleigh

Excited state dynamics

Fluorescência

Fluorescent decay time

Hiperpolarizabilidades

Hiperpolarizabilities

Hyper-Rayleigh scatering

Nonlinear absorption

Nonlinear refraction

Oligômeros de anilina

Refração não linerar

Varredura-Z

Z-scan

Chaînes peptidiques modèles en détente supersonique : refroidissement conformationnel, structures et dynamique des états excités étudiés par modélisation Monte-Carlo, spectroscopies laser et chimie quantique / Supersonic expansion of model peptides : conformational cooling, structures and excited states dynamics studied by Monte-Carlo methods, laser spectroscopy and quantum chemistry

Loquais, Yohan

10 July 2013

Cette thèse présente une étude expérimentale et théorique de petites chaines peptidiques modèles en phase gazeuse. Le premier objectif de ce travail consistait à déterminer les conformations préférentiellement adoptées par ces molécules isolées, en vue d’obtenir des informations sur les interactions intra- et inter-moléculaires intervenant dans ces systèmes flexibles. La stratégie expérimentale utilisée associait la vaporisation laser à une détente supersonique et reposait sur la spectroscopie laser de double résonance IR-UV. L’attribution finale des structures a ensuite été réalisée par comparaison des spectres expérimentaux à des spectres issus de calculs de chimie quantique au niveau DFT-D. Dans un deuxième temps, il s’agissait d’étudier la dynamique de relaxation électronique de ces systèmes par spectroscopie pompe-sonde et mesures de fluorescence, et en particulier la dépendance de celle-ci avec la structure secondaire des peptides modèles. La question de la population conformationnelle de molécules flexibles en phase gazeuse est un sujet délicat et bien souvent éludée car les distributions observées expérimentalement résultent d’un passage hors équilibre lors de la détente supersonique, définissant ainsi une température conformationnelle effective. Un modèle statistique a été développé, décrivant le refroidissement et les isomérisations subis durant la détente par une molécule. Les résultats de ces modélisations reproduisent les tendances d’évolution des rapports d’abondances entre conformations observés expérimentalement et permettent de fournir des ordres de grandeurs relatifs aux processus mis en jeu (nombre de collisions efficaces, trajectoire dans la détente après désorption, températures finales) ainsi qu’une meilleure compréhension des processus de refroidissement et de relaxation conformationnelle. Les études conformationnelles ont été appliquées à deux systèmes modèles choisis pour étudier des interactions structurantes intervenant dans les protéines : les interactions protéines-solvant et les interactions hydrophobes. L’étude des complexes (Ac­Phe­NH₂ : H₂O) et (Ac­Phe­NHMe : H₂O) ont permis d’identifier les sites de solvatation préférentiellement occupés par une molécule d’eau et ainsi de proposer des mécanismes de formation des complexes dans la détente supersonique. Le rôle structurant très fort des interactions hydrophobes entre chaînes latérales aromatiques a pu être mis en évidence en étudiant deux peptides modèles contenant un enchainement de plusieurs acides aminés phénylalanine : Ac­Phe­Phe­NH₂ et Ac­Phe­Phe­Phe­NH₂. L’étude des dynamiques de relaxation du premier état excité ππ*, réalisée sur divers peptides modèles, a permis de démontrer la présence d’effets conformationnels importants. Des calculs de chimie quantique (TDDFT et CC2) réalisés sur les systèmes Ac-Phe NH₂ et Ac-Phe NHMe ont montré que cet effet pouvait être expliqué par un transfert d’excitation depuis le cycle aromatique présent sur la chaîne latérale vers les liaisons peptidiques de la chaine principale. Enfin, l’ajout d’une molécule d’eau sur le peptide Ac-Phe NH₂ semble ouvrir de nouvelles voies ultrarapides de relaxation non-radiative. / The very good spectral resolution of laser spectroscopy achieved in the gas phase is a powerful tool to study the folding properties and the hydrogen bonding network of flexible molecules such as small peptide chains. The experimental strategy used in this work to determine the structural properties of these systems is based on IR-UV double resonance spectroscopy and combines laser vaporisation with a supersonic expansion. The final assignment then requires a comparison between experimental spectra and DFT-D calculations. The conformational selectivity brought by gas phase laser spectroscopy also makes it possible to study the dependence of the dynamics of relaxation of electronic excited states of model peptides with their secondary structure by using pump-probe methods or fluorescence detection. The issue of the conformational population of flexible molecules cooled in a supersonic expansion is a difficult issue, often disregarded due to the nonequilibrium processes that control the distributions experimentally observed. A statistical model was developed in order to describe this collisional cooling and the isomerizations experienced by one molecule during the expansion. These calculations were consistent with the experimental trends in the population ratios between conformations, they have provided orders of magnitude for the different processes involved (number of collision, trajectory in the expansion after desorption, final temperatures) and a better understanding of the cooling processes and the conformational relaxation. The conformational studies have been applied to two model systems selected to investigate structural interactions involved in proteins: protein-solvent interactions and hydrophobic interactions. The microhydrated protected phenylalanines (Ac­Phe­NH₂ : H₂O) and (Ac­Phe­NHMe : H₂O) were used to locate the solvation sites preferentially occupied by a water molecule, which then helped to propose a mechanism for the formation of hydrates in the supersonic expansion. The strong structuring properties of hydrophobic interactions between aromatic side chains has been revealed by studying two model peptides containing a sequence of phenylalanine amino acids: Ac­Phe­Phe­NH₂ and Ac­Phe­Phe­Phe­NH₂. A comparative study of the relaxation dynamics of the first ππ* excited state performed on various model peptides has demonstrated the existence of a strong conformational effect. TDDFT and CC2 calculations carried out on the protected phenylalanines have shown that this effect could be explained by an excitation transfer from the aromatic ring of a side chain toward a peptide bond of the backbone. Finally, adding a water molecule to the protected phenylalanine is also found to open new ultrafast channels of nonradiative deactivation.

Peptides

Structures secondaires

Spectroscopie laser

Refroidissement conformationnel

Spectroscopie en phase gazeuse

Dynamique de relaxation

Chimie quantique

Peptides

Secondary structures

Laser spectroscopy

Conformational cooling

Gas phase spectroscopy

Excited state dynamics

Quantum chemistry