Global ETD Search

141	The quantum dynamics of the diffusion of dissociatively adsorbed diatomic molecules Reis Firmino, Thiago Diamond 27 May 2014 (has links) (PDF) The work carried out during this thesis focuses on the quantum dynamics of the diffusion of hydrogen atoms on a surface of palladium (111). The study of the 3D system allowed us to detail the infrared spectrum of H/Pd (111), showing the existence of different adsorption sites on which localized states exist that are strongly coupled (Fermi resonance). This phenomenon governs the diffusion of hydrogen atoms in an ultra-fast time scale (fs).The study of the (6D) H2/Pd(111) system has shown that the transitions observed are in fact transition bands between several quasi-degenerate adsorption states. The agreement between the calculated and measured values is significantly less good than that between the data calculated for the 3D system and the measured data. Does adsorbed hydrogen on palladium exist in the form of a weakly bound H2 molecule? This thesis has provided some answers to this question, which remains open, hovewer, to some extent. [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Dissociative adsorption Quantum diffusion Surface potential energy Vibrational spectroscopy Fermi resonance
142	Vibrational spectroscopy of keratin fibres : A forensic approach Panayiotou, Helen January 2004 (has links) Human hair profiling is an integral part of a forensic investigation but it is one of the most technically difficult subjects in forensic science. This thesis describes the research and development of a novel approach for the rapid identification of unknown human and other related keratin fibres found at a crime scene. The work presented here is developed systematically and considers sample collection, sample preparation, analysis and interpretation of spectral data for the profiling of hair fibres encountered in criminal cases. Spectral comparison of fibres was facilitated with the use of chemometrics methods such as PCA, SIMCA and Fuzzy Clustering, and the less common approach of multi-criteria decision making methodology (MCDM). The aim of the thesis was to investigate the potential of some vibrational spectroscopy techniques for matching and discrimination of single keratin hair fibres in the context of forensic evidence. The first objective (chapter 3) of the thesis was to evaluate the use of Raman and FT-IR micro-spectroscopy techniques for the forensic sampling of hair fibres and to propose the preferred technique for future forensic hair comparisons. The selection of the preferred technique was based on criteria such as spectral quality, ease of use, rapid analysis and universal application to different hair samples. FT-IR micro-spectroscopy was found to be the most appropriate technique for hair analysis because it enabled the rapid collection of spectra from a wide variety of hair fibres. Raman micro-spectroscopy, on the other hand, was hindered with fluorescence problems and did not allow the collection of spectra from pigmented fibres. This objective has therefore shown that FT-IR micro-spectroscopy is the preferable spectroscopic technique for forensic analysis of hair fibres, whilst Raman spectroscopy is the least preferred. The second objective (chapter 3) was to investigate, through a series of experiments, the effect of chemical treatment on the micro-environment of human hair fibres. The effect of bleaching agents on the hair fibres was studied with some detail at different treatment times and the results indicate a significant change in the chemical environment of the secondary structure of the hair fibre along with changes in the C-C backbone structure. One of the most important outcomes of this research was the behaviour of the fÑ-helix during chemical treatment. The hydrogen bonding in the fÑ-helix provides for the stable structure of the fibre and therefore any disruption to the fÑ-helix will inevitably damage the molecular structure of the fibre. The results highlighted the behaviour of the fÑ-helix, which undergoes a significant decrease in content during oxidation, and is partly converted to a random-coil structure, whilst the fÒ-sheet component of the secondary structure remains unaffected. The reported investigations show that the combination of FT-IR and Raman micro-spectroscopy can provide an insight and understanding into the complex chemical properties and reactions within a treated hair fibre. Importantly, this work demonstrates that with the aid of chemometrics, it is possible to investigate simultaneously FT-IR and Raman micro-spectroscopic information from oxidised hair fibres collected from one subject and treated at different times. The discrimination and matching of hair fibres on the basis of treatment has potential forensic applications. The third objective (chapter 4) attempted to expand the forensic application of FT-IR micro-spectroscopy to other keratin fibres. Animal fibres are commonly encountered in crime scenes and it thus becomes important to establish the origin of those fibres. The aim of this work was to establish the forensic applications of FT-IR micro-spectroscopy to animal fibres and to investigate any fundamental molecular differences between these fibres. The results established a discrimination between fibres consisting predominantly of fÑ-helix and those containing mainly a fÒ-sheet structure. More importantly, it was demonstrated through curve-fitting and chemometrics, that each keratin fibre contains a characteristic secondary structure arrangement. The work presented here is the first detailed FT-IR micro-spectroscopic study, utilising chemometrics as well as MCDM methods, for a wide range of keratin fibres, which are commonly, found as forensic evidence. Furthermore, it was demonstrated with the aid of the rank ordering MCDM methods PROMETHEE and GAIA, that it is possible to rank and discriminate keratin fibres according to their molecular characteristics obtained from direct measurements together with information sourced from the literature. The final objective (chapter 5) of the thesis was to propose an alternative method for the discrimination and matching of single scalp human hair fibres through the use of FT-IR micro-spectroscopy and chemometrics. The work successfully demonstrated, through a number of case scenarios, the application of the technique for the identification of variables such as gender and race for an unknown single hair fibre. In addition, it was also illustrated that known hair fibres (from the suspect or victim) can be readily matched to the unknown hair fibres found at the crime scene. This is the first time that a substantial, systematic FT-IR study of forensic hair identification has been presented. The research has shown that it is possible to model and correlate individual¡¦s characteristics with hair properties at molecular level with the use of chemometrics methods. A number of different, important forensic variables of immediate use to police in a crime scene investigation such as gender, race, treatment, black and white hair fibres were investigated. Blind samples were successfully applied both to validate available experimental data and extend the current database of experimental determinations. Protocols were posed for the application of this methodology in the future. The proposed FT-IR methodology presented in this thesis has provided an alternative approach to the characterisation of single scalp human hair fibres. The technique enables the rapid collection of spectra, followed by the objective analytical capabilities of chemometrics to successfully discriminate animal fibres, human hair fibres from different sources, treated from untreated hair fibres, as well as black and white hair fibres, on the basis of their molecular structure. The results can be readily produced and explained in the courts of law. Although the proposed relatively fast FT-IR technique is not aimed at displacing the two slower existing methods of hair analysis, namely comparative optical microscopy and DNA analysis, it has given a new dimension to the characterisation of hair fibres at a molecular level, providing a powerful tool for forensic investigations. vibrational spectroscopy spectroscopy keratin fibres forensic evidence PCA SIMCA fuzzy clustering FT-IR micro-spectroscopy Raman spectroscopy forensic hair identification chemometrics DNA analysis.
143	Synthèse et caractérisation de verres d’oxyde d’argent : évolution sous rayonnements ionisants et structuration multi-échelle par laser femtoseconde / Synthesis and characterization of silver-containing glasses : evolution under ionizing irradiation and femtosecond laser multiscale structuring Desmoulin, Jean-Charles 02 December 2016 (has links) Les verres de phosphates de zinc et gallium contenant de l’argent ont permis des développements originauxau travers de la structuration d’architectures photoniques multi-échelles innovantes en volume, en surfaceou sur fibre, et également à travers l’ingénierie de composition chimique du matériau. Un taux accru d’oxyded’argent permet de maximiser la quantité de paires au sein de la matrice vitreuse lors de la synthèse dumatériau. Ce dimère favorise les processus d’agrégation conduisant à la formation d’espèces lors del’interaction locale entre le verre et le laser femtoseconde infrarouge. Une étude par spectroscopie RPEmenée sur des échantillons irradiés par des sources ionisantes a permis de montrer que le débit de dose estprépondérant quant au contrôle des processus chimiques. Des centres à électron et à trou sont les espècesmajoritairement stabilisées à faible débit de dose, alors que la formation d’agrégats d’argent luminescentsintervient pour des puissances crête élevées typiques des lasers ultra-courts. Le caractère local de lastructuration par Direct Laser Writing a permis de créer des objets 3D originaux. L’analyse fine de ladistribution chimique au sein d’objets fluorescents a permis de montrer clairement une zone de déplétion enions argent au centre. Les effets de migration d’ions depuis le centre du faisceau laser vers le bord externea ainsi été mis en évidence. Le dopage des verres photosensibles par des ions europium a permis de montrerdes effets de synergie entre agrégats d’argent photo-inscrits et lanthanides trivalent. En effet, une exaltationde l’émission de luminescence de ces derniers à l’endroit des structurations laser a été mesurée. / The silver-containing phosphate glasses allowed original developments throughout the microstructuring ofarchitectures for innovative photonic in the volume, at the surface or in the fibered material. The chemicalengineering of the material plays an important role from this point of view. An increasing silver oxide ratioleads to an important quantity of pairs in the pristine glass matrix. This dimer in favor of the aggregationprocess bringing to the production of species during the interaction between the glass and the infraredfemtosecond laser. A study conducted by EPR spectroscopy on irradiated samples (ionizing sources)demonstrated that the dose rate is predominant for the control of the involved chemical process. Mainly,electron and holes are stabilized at low dose rate whereas the formation of luminescent silver clusters occursfor high peak power typical of ultra-short lasers. The Direct Laser Writing process allows local structuring ofthe matter and resulted in original tridimensional patterns. The fine chemical distribution analysis insideannular fluorescent objects clearly showed a depletion zone of the silver concentration in the center. Ionicmigration effects from the center towards the edges of the laser beam are then highlighted. The Eu3+-dopedphotosensitive glasses emphasized a synergy between photo-induced silver clusters and trivalentlanthanides. Indeed, a luminescence exaltation associated to the europium emission is measured. Verre photosensible Phosphate Argent Agrégat Europium trivalent Interaction lase rmatière Laser femtoseconde Spectroscopie vibrationnelle Spectroscopie optique Spectroscopie magnétique Photosensitive glass Phosphate Silver Cluster Trivalent Europium Laser-matter interaction Femtosecond laser Vibrational spectroscopy Optical spectroscopy Magnetic spectroscopy 661.43
144	Physical phenomena in metal-organic frameworks : mechanical, vibrational, and dielectric response Ryder, Matthew January 2017 (has links) This thesis entails the utilisation of ab initio density functional theory (DFT) in conjunction with neutron and synchrotron spectroscopy to study the mechanical, vibrational, and dielectric response of metal-organic framework (MOF) materials at the molecular level. MOFs are crystalline materials with nanoscale porosity, which have garnered immense scientific and technological interest for a wide variety of innovative engineering applications. One part of the thesis involves using low-frequency lattice vibrations to characterise the various physical motions that are possible for framework materials. These collective modes detected at terahertz (THz) frequencies have been used to reveal a broad range of exciting possibilities. New evidence has been established to demonstrate that THz modes are intrinsically linked to anomalous elasticity underpinning gate-opening and pore-breathing mechanisms, and to shear-induced phase transitions and the onset of structural instability. The phenomenon of molecular rotor mechanisms and trampoline-like motions are also observed, along with the first experimental confirmation of coordinated shear dynamics. Additionally, a new method to characterise the effects of temperature, and hence thermally-induced structural amorphisation is reported. Finally, for the first time, the frequency-dependent (dynamic) dielectric response of MOF materials, across the extended infrared (IR) spectral region was reported. The results were obtained from experimental synchrotron radiation IR reflectivity and DFT to reveal the low-&kcy; dielectric response of MOFs and established structure-property trends that highlight them as promising systems for microelectronic device applications.
145	Jet-Cooled Molecular Spectroscopy from the Microwave to the Ultraviolet Piyush Mishra (8028629) 25 November 2019 (has links) The present thesis shows how versatile and important the field of gas-phase spectroscopy under supersonic expansion conditions can be to understand fundamental intermolecular and intramolecular interactions. We have employed spectroscopic techniques over a very broad range spanning from microwave (2-18 GHz), through infrared (2600-4000 cm-1) and ultraviolet (350-250 nm) region, studying therotational, vibrational and electronic properties,respectively. These techniques use either chirped-pulse based (broadband rotational spectroscopy) or laser based methods (vibrational and electronic spectroscopy), and their usage depends on the types of information of particular interest and the chemical system requirements of specific techniques. The analytes are brought into the gas phase and supersonically cooled to their zero-point vibrational level to perform rotational and vibrationallyresolved IR/UV spectroscopy, including conformer-specific techniques. The variety of small organic molecular systemsstudied include phenyl-containing hydrocarbons, water containing clusters, heteroatom containing organic molecules with and without phenyl ring, fused aromatic molecules, bichromophoric molecules and pyrolysis reaction intermediates. Apart from gaining invaluable fundamental knowledge of the various interactions, we also observe interesting quantum-physical phenomena like tunneling and large amplitude motions that provide further insight into the molecular world. Molecular Physics Molecular spectroscopy microwave infrared ultraviolet rotational spectroscopy vibrational spectroscopy electronic spectroscopy Supersonic Molecular Beams Supersonic Jet Spectroscopy chirped-pulse spectroscopy laser spectroscopy
146	Syntéza a studium krystalických materiálů pro NLO / Synthesis and study of crystalline materials for NLO Janatková, Tereza January 2018 (has links) This thesis is focused on preparation and study of new compounds of chosen organic bases with potential use in nonlinear optics. 2-amino-5-nitropyrimidine, 2-amino-4-methylpyrimidine and their salts with inorganic and organic acids are compounds of the main interest. Diffraction and vibrational-spectroscopic methods of characterization were used in combination with quantum chemical calculation methods. Another aim of this thesis was preparation of new salts of chosen pyrimidine derivates with the use of methylsulphonic acid. Part of this section is devoted to completion of pyridinium methylsulphonate phase transition and nonlinear optical property studies.
147	Etude optique du couplage vibroélectronique à l'interface entre boîtes quantiques semiconductrices et molécules organiques / Optical study of vibroelectronic coupling at the interface between semiconductor quantum dots and organic molecules Noblet, Thomas 18 September 2019 (has links) Les processus physico-chimiques se produisant au sein des nanoparticules que sont les boîtes quantiques semiconductrices (QDs) sont à l'origine d'une nouvelle classe de sondes fluorescentes trouvant des applications en catalyse, en reconnaissance moléculaire et en imagerie. Le confinement quantique des électrons aux sein de ces objets luminescents, qui donne lieu à leur structure excitonique si particulière, permet de tirer simultanément profit de leurs propriétés optiques d'absorption et d'émission dans la gamme spectrale visible, et ce, dans le but de faciliter la détection et l’identification des espèces chimiques situées dans leur environnement proche. Dans ce contexte, nous nous sommes intéressés à des QDs de 3 à 4 nm de diamètre, composées d’un alliage ternaire de cadmium, de tellure et de soufre, et fonctionnalisées par des ligands mercaptocarboxyliques. De manière à déterminer l’ensemble de leurs propriétés structurales, chimiques et optoélectroniques, nous les avons tout d’abord caractérisées à l’état de solutions colloïdales par diverses techniques expérimentales : microscopie électronique, zêta-métrie, analyse par diffusion dynamique de la lumière, spectroscopies de rayons X, d’absorption UV-visible et d’émission de fluorescence. Ceci nous a permis de déduire la composition chimique des nanocristaux, leur structure cristalline, leur taille, leur dispersion en taille, la composition chimique de leurs ligands, les énergies propres de leurs états électroniques, leur moments dipolaires de transition et leur section efficace d’absorption. Fort de ces connaissances, nous avons pu développer un modèle analytique pour calculer la susceptibilité diélectrique des QDs et extraire de cette manière leur fonction de réponse linéaire, véritable carte d’identité optoélectronique. Nous avons ensuite optimisé la conception par voie chimique d’interfaces composées de QDs et de différentes espèces moléculaires organiques, dépôts réalisés sous forme de monocouches ou de films épais sur des substrats solides plans de silicium, de verre et de fluorure de calcium fonctionnalisés par des organosilanes. Ces interfaces substrat/QDs/molécules ont alors été étudiées par spectroscopie linéaire d’absorption UV-visible et par spectroscopie optique non-linéaire de génération de fréquence-somme (SFG). La première nous a permis de déterminer la densité superficielle des QDs déposés et d’en caractériser la stabilité temporelle, et la seconde, qui combine deux lasers visible et infrarouge, d’identifier la signature vibrationnelle des ligands recouvrant les QDs. Grâce à ces échantillons, nous avons alors montré par spectroscopie SFG deux couleurs l’existence d’un couplage vibroélectronique entre les QDs et leur environnement moléculaire. En particulier, nous avons démontré que l’amplitude de vibration des modes moléculaires associés aux ligands des QDs et aux organosilanes greffés sur les substrats est maximale lorsque les QDs sont eux-mêmes stimulés par la lumière visible dans leur premier état excitonique. Cette démonstration expérimentale s’accompagne par ailleurs d’une démonstration théorique : en utilisant les diagrammes de Feynman dans l’espace des fréquences imaginaires de Matsubara, nous avons déterminé l’expression analytique de la susceptibilité non-linéaire d’ordre 2 du complexe QD/molécule. Nous avons alors vérifié que l’hypothèse d’un couplage dipolaire entre QDs et molécules menait à une modélisation de la réponse vibrationnelle SFG compatible avec les mesures expérimentales. De cette manière, l’existence d’un couplage vibroélectronique de nature dipolaire entre boîtes quantiques et molécules est attesté. / The different physico-chemical processes occurring within semiconductor quantum dots (QDs) give rise to a new class of fluorescent probes and a wide range of applications in catalysis, molecular recognition and imaging. Within these luminescent nanoparticles, the quantum confinement of electrons, which leads to their very special excitonic structure, allows us to benefit from both their absorption and emission optical properties, with the specific aim of fostering the detection and the identification of the chemical species located in their direct environment. Within this framework, we were interested in 3 to 4-nm-sized QDs composed of ternary alloys of cadmium, telluride and sulfur, and functionalized by mercaptocarboxylic ligands. In order to determine their structural, chemical and optoelectronic properties, we first characterized them thanks to several experimental techniques: electron microscopy, zeta potentiel measurements, dynamic light scattering analysis, X-ray, UV-visible and fluorescence spectroscopies. This enabled us to deduce the chemical composition of the nanocrystals, their crystal structure, size, size-dispersion, the chemical composition of their ligands, the eigenenergies of their electronic states, their transition dipole moments and absorption cross-sections. Given all those results, we succeeded in deriving an analytical model of the QD dielectric susceptibility and extracting in this way their linear response function. Then, we optimized the chemical synthesis of nanostructured interfaces made of QDs and various molecular species through the use of flat solid substrates of silicon, glass and calcium fluoride functionalized with organosilanes. These substrate/QDs/molecules interfaces were studied by linear UV-visible absorption spectroscopy and by sum-frequency generation non-linear optical spectroscopy (SFG). The former allowed us to determine the surface density of the deposited QDs and to characterize their stability over time, while the later, which combines two visible and infrared lasers, enabled us to identify the vibrational signature of the QD ligands. Thanks to those samples probed by two-colour SFG spectroscopy, we therefore shew the existence of a vibroelectronic coupling between QDs and their molecular surroundings. Especially, we demonstrated that the vibration amplitudes associated to the molecular modes of the QD ligands and the organosilanes grafted on the substrates are maximum when the QDs are excited by visible light into their first excitonic state. This experimental demonstration is further supported by theoretical considerations: Feynman diagrams in Matsubara imaginary-time representation were used to determine the analytical expression of the second-order nonlinear susceptibility of the QD/molecule bipartite system. We thus verified that the hypothesis of a dipolar coupling between QDs and molecules resulted in a modeling of the vibrational SFG response which proved to be in complete agreement with the experimental measurements. Thus, we evidenced the existence of a dipolar vibroelectronic coupling between quantum dots and molecules. Optique non-linéaire Spectroscopie vibrationnelle Génération de fréquence-somme (SFG) Spectroscopie UV-visible Fluorescence Boîtes quantiques semiconductrices Nonlinear optics Vibrational spectroscopy Sum-Frequency Generation (SFG) UV-visible spectroscopy Fluorescence Semiconducting quantum dots
148	Ultrafast Time Resolved and Computational Studies of Diazo and Diazirine Excited States, and of Carbenes Zhang, Yunlong 23 August 2010 (has links) No description available. Chemistry ultrafast laser flash photolysis vibrational spectroscopy diazo diazirine excited state carbene computational study calculations ultrafast IR ultrafast UV-Vis phenylcarbene S<sub>1</sub> state photochemistry
149	Theoretical Investigation and Structural Assignment of Small Metal Oxide Clusters Müller, Fabian 13 December 2021 (has links) Anhand von theoretischen Untersuchungen wird eine umfassende Beschreibung von kleinen Metalloxidclustern gegeben. Bei den untersuchten Systemen handelt es sich um Aluminium- und Eisenoxid-Ionen sowie entsprechende Oxid-Cluster, die beide Metalle enthalten. Neben der Bestimmung der geometrischen Struktur der Cluster werden auch die allgemeinen elektronischen Eigenschaften der eisenhaltigen Verbindungen untersucht. Alle Vorhersagen werden durch Vergleich mit verfügbaren experimentellen Ergebnissen -- hauptsächlich aus der Infrarot-Photodissoziations- und der Photoelektronenspektroskopie -- überprüft und bewertet. Soweit möglich werden die Bewegungen von Atomen oder kleinen Gruppen innerhalb der Cluster einzelnen experimentellen Signalen zugeordnet. Besondere Aufmerksamkeit wird dem Eisendioxidmolekül und seinem Anion gewidmet. Es wird mit spezialisierten Wellenfunktionsmethoden untersucht, mit denen ab initio Franck-Condon-Simulationen einschließlich nicht-adiabatischer und Spin-Orbit-Kopplungen für die Photoionisation des Anions erstellt werden. Sie liefern Erklärungen für die komplizierte Schwingungsstruktur des experimentellen hochauflösenden Photoelektronenspektrums. / By means of theoretical investigations, a comprehensive description of small metal oxide clusters is given. The studied systems are aluminum and iron oxide ions as well as respective bi-metallic oxide clusters. Besides the determination of the geometrical structure of the clusters, the general electronic properties of the iron-containing compounds are investigated. All predictions are checked and assessed by comparison with available experimental results, mainly infrared photodissociation and photoelectron spectroscopy measurements. As far as possible, motions of atoms or small groups within the clusters are assigned to distinct experimental vibrational features. Particular attention is paid to the iron dioxide molecule and its anion. It is studied with sophisticated wave function methods based on which ab initio Franck-Condon simulations for the photodetachment from the anion, including non-adiabatic and spin-orbit couplings, are generated. They provide explanations for the complicated vibrational structure of the experimental high-resolution photoelectron spectrum. Eisenoxidcluster Aluminiumoxidcluster Hydratation Dichtefunktionaltheorie Multireferenzmethoden Schwingungsspektroskopie Renner-Teller-Effekt Iron Oxide Clusters Aluminum Oxide Clusters Hydration Density Functional Theory Multi-Reference Methods Vibrational Spectroscopy Renner-Teller Effect 541 Physikalische Chemie VE 7047 VG 9307 VE 5657 VH 8082 ddc:541
150	Ultrafast dynamics of phospholipid-water interfaces studied by nonlinear time-resolved vibrational spectroscopy Costard, Rene 09 May 2014 (has links) Geladene Phosphatgruppen sind von wesentlicher Bedeutung für die Hydratisierung von Phospholipiden und DNS. Hydratisierungshüllen spielen eine wichtige Rolle für die Ausbildung und Stabilisierung von Zellmembranen und der DNS-Doppelhelixstruktur. In dieser Arbeit werden elementare Phosphat-Wasser-Wechselwirkungen in einem Phospholidmodellsystem – sogenannten inversen Mizellen - mit variablen Wassergehalt zwischen einem und 16 Wassermolekülen pro Phospholipid untersucht. Die schnellsten Prozesse an den Grenzflächen wie z.B. Phosphat-Wasser-Wasserstoffbrückendynamik und Schwingungsenergieumverteilung finden auf einer Femto- bis Pikosekundenzeitskala statt. Molekulare Schwingungen sind sensitive lokale Sonden für die Struktur und Dynamik. Deshalb ermöglicht Femtosekunden-Schwingungsspektroskope, insbesondere zweidimensionale Infrarotspektroskopie (2D IR) und Pump-Probe-Spektroskopie in einem breiten Spektralbereich, die Dynamik mikroskopischer Phosphat-Wasser-Wechselwirkungen in Echtzeit zu beobachten. Wir zeigen die ersten zweidimensionalen Infrarotspektren von Phosphat-Streckschwingungen, die unabhängig vom Wassergehalt grenzflächensensitive Sonden darstellen. Solche Spektren belegen, dass die schnellsten strukturellen Fluktuationen der Phospholipid-Kopfgruppen auf einer 300-fs Zeitskala ablaufen, wohingegen die Phosphat-Wasser-Wasserstoffbrücken länger als 10 ps bestehen bleiben. Die Schwingungsdynamik intramolekularer Wasserschwingungen, d.h. der OH-Streck- und Biegeschwingung, zeigen, dass sich kleine Wasserpools um die Phosphatgruppen bilden, sobald drei oder mehr Wassermoleküle pro Phospholipid vorliegen. Solche Wasserpools dienen als effiziente Wärmesenken für intramolekulare Schwingungen des Wassers und der Phosphatgruppen. / Charged phosphate groups are the major hydration sites of biomolecules such as phospholipids and DNA. Hydration shells play a key role in the formation and stabilization of cell membranes and the DNA double helix structure. Here, we introduce phospholipid reverse micelles with variable water content (between one and sixteen water molecules per phospholipid) as a model system to study elementary phosphate-water interactions. The fastest processes at phosphate-water interfaces , e.g. hydrogen-bond dynamics and vibrational energy transfer occur on a femto- to picosecond time scale. Since molecular vibrations are sensitive local probes of the structure and dynamics, the use of femtosecond vibrational spectroscopy, in particular two-dimensional infrared spectroscopy (2D IR) and pump-probe spectroscopy in a broad spectral range, allow for the observation of microscopic phosphate-water interactions in real time. We present the first two-dimensional infrared spectra of phosphate stretching vibrations that represent true interfacial probes independent of the hydration level. Such spectra reveal that the fastest structural fluctuations of phospholipid headgroups occur on a 300-fs timescale whereas phosphate-water hydrogen bonds are preserved for >10 ps. Vibrational dynamics of intramolecular water vibrations, i.e., the OH stretching and bending modes show that small water pools around the phosphate groups form when three or more water molecules per phospholipid are present. Such water pools act as efficient heat sinks of excess energy deposited in intramolecular vibrations of water or the phosphate groups. Wasser Phospholipid Inverse Mizelle Phosphat-Wasser-Wechselwirkung Wasserstoffbrücke strukturelle Dynamik ultraschnelle Schwingungsspektroskopie 2D IR water phospholipid reverse micelle phosphate-water interaction hydrogen bond structural dynamics ultrafast vibrational spectroscopy 2D IR 530 Physik 29 Physik, Astronomie UR 4400 VG 9307 WD 5400 ddc:530

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