Global ETD Search

91	Interpreting time-resolved spectra and excited state reactivity with computational methods Lamb, Robert 01 May 2020 (has links) Light-harvesting compounds are developed for a variety of purposes pertaining to areas such as energy-capture, chemical transformations, and lighting. There is a need to better understand the reactivity and excited state properties of these compounds. Many experiments focus on gleaning information about reactivity by observing spectral changes over time intervals ranging from femtoseconds to minutes (IR, UV-VIS, and UV-VIS pump-probe spectroscopy). This dissertation focuses on the interpretation of the experimental data from a computational perspective and methodological studies to determine reasonable levels of theory for each system. Three vignettes of this approach will be discussed. First, a mononuclear tungsten complex was found to be capable of self-sensitized catalytic H2 production. Experimental mechanistic studies employed time-resolved IR spectroscopy to capture spectral signatures of potential catalytic intermediates. DFT computational methods were utilized to predict geometries, energies, and harmonic stretching frequencies of a variety of catalytic intermediates that correlate rather well with experiment. For studying the excited state, the prototypical system that is both well-known and well-behaved is the [Ru(bpy)3]2+ ion. This complex undergoes a MLCT excitation and ultimately forms a long-lived 3MLCT state with a lifetime on the order of µs. While several computational studies exist, a systematic study on what dictates an appropriate level of theory for correctly describing this system is absent from the literature. We conduct a systematic study of a series of DFT functionals and basis set combinations to evaluate the relative energies of the MLCT and MC states, as well as correctly predicting the character of excitations observed in the transient UV-VIS spectra of the MLCT excited state. Finally, the absorption and emission spectra of a series of polycyclic aromatic azaborines were simulated and compared to their experimental values. Experimentally, some compounds exhibit large, solvent-dependent Stokes shifts consistent with CT excitations. Unfortunately, the excited state chemistry is not so straightforward and some of these compounds may become deprotonated in the ES, thus resulting in a charge-separated state. As a by-product of this project, the results from each method suggest that, contrary to literature precedent, typical hybrid functionals appear to overestimate the CT character of the computed excitations. absorption emission excited state Ru(bpy)3 TD-DFT transition character
92	Charge Distribution in the MLCT States of <i>trans</i>-M<sub>2</sub>L<sub>2</sub>L’<sub>2</sub> and M<sub>2</sub>L<sub>4</sub> Compounds Studied by Femtosecond Spectroscopy, where M= Mo and W Jiang, Changcheng January 2016 (has links) No description available. Chemistry
93	Femtosecond Transient Absorption Study of Excited-State Dynamics in DNA Model Systems:Thymine-dimer Containing Trinucleotides, Alternate Nucleobases,and Modified Backbone Dinucleosides Chen, Jinquan 28 August 2012 (has links) No description available. Chemistry DNA excited-state dynamics transient absorption trinucleotide hypoxanthine methylxanthine adenine dinucleoside
94	Kvantové kritické jevy v konečných systémech / Kvantové kritické jevy v konečných systémech Kloc, Michal January 2013 (has links) Singularities in quantum spectra - ground state and excited-state quantum phase transitions - are often connected with singularities in the classical limit of the system and have influence on other properties, such as quantum entanglement, as well. In the first part of the thesis we study quantum phase transitions within the U(2)-based Lipkin model. The relation between quasistationary points of the classical potential and the respective singularities in the spectrum is shown. In the second part, a system of two-level atoms interacting with electromagnetic field in an optical cavity is studied within two simplified models (non-integrable Dicke model and its integrable approximation known as Jaynes-Cummings model). The behaviour of quantum entanglement in these models is shown with a focus on the vicinity of the singular points.
95	Astrochimie expérimentale : cinétique des réactions neutre-neutre à basse température et pertinence pour la chimie des atmosphères planétaires et des nuages interstellaires / Experimental astrochemistry : the kinetics of neutral-neutral reactions at low temperature and their relevance to the chemistry of planetary atmospheres and interstellar clouds Núñez Reyes, Dianailys 19 March 2019 (has links) Les 50 dernières années ont été caractérisées par le développement rapide de l’astrochimie. Plus de 150 réactions entre espèces neutres ont déjà été étudiées aux basses températures qui sont celles du le milieu interstellaire et des atmosphères planétaires. Néanmoins, les constantes de vitesse, et la nature des produits, restent inconnus pour de nombreuses réactions potentiellement importantes pour caractériser ces milieux. Nous avons effectué des études cinétiques pour des processus réactifs, et non réactifs, entre des atomes dans un état électronique excité [C(1D), O(1D) et N(2D)] et plusieurs molécules stables afin de quantifier leur importance dans la chimie des atmosphères planétaires. Nous avons aussi étudié la réaction entre les atomes de carbone dans leur état électronique fondamental (3P) et l’eau, confirmant l’importance, pour certaines réactions avec barrière, de l’effet tunnel pour la réactivité à basse température. Les constantes de vitesse et les rapports de branchement pour ces processus ont été déterminés dans la gamme de température entre 50 et 296 K en utilisant un appareil CRESU, les atomes étudiés ont été produits par photolyse à l’aide d’un laser pulsé (PLP) et détectés par fluorescence induite dans l’ultraviolet sous vide (VUV LIF). / The last 50 years have been characterized by the fast development of astrochemistry as a science. To date, more than 150 gas-phase neutral-neutral reactions have been investigated at low temperatures relevant to planetary atmospheres and in cold regions of the interstellar medium. However, the rate constants and nature of the products for many potentially important gas-phase processes remain unknown. We performed kinetic studies of reactive and non-reactive removal processes between electronically excited atoms [C(1D), O(1D) and N(2D)] with several molecules in order to quantify their importance in the chemistry of planetary atmospheres. Furthermore, we also investigated the reaction between carbon atoms in their ground electronic state (3P) with water, providing new evidence of a quantum mechanical tunnelling mechanism at low temperatures, which could play an important role in the chemistry of interstellar clouds. Rate constants and branching ratios for these processes were determined over the 50 - 296 K temperature range using a CRESU (Cinétique de Réaction en Ecoulement Supersonique Uniforme) apparatus coupled with pulsed laser photolysis (PLP) and vacuum ultraviolet laser induced fluorescence (VUV LIF). Astrochimie Cinétique chimique Réactions en phase gazeuse Atomes à l'état excité CRESU Astrochemistry Chemical kinetics Gas-phase reactions Excited state atoms CRESU
96	Ultrafast Exciton Dynamics at Molecular Surfaces Monahan, Nicholas R. January 2015 (has links) Further improvements to device performance are necessary to make solar energy conversion a compelling alternative to fossil fuels. Singlet exciton fission and charge separation are two processes that can heavily influence the power conversion efficiency of a solar cell. During exciton fission one singlet excitation converts into two triplet excitons, potentially doubling the photocurrent generated by higher energy photons. There is significant discord over the singlet fission mechanism and of particular interest is whether the process involves a multiexciton intermediate state. I used time-resolved two-photon photoemission to investigate singlet fission in hexacene thin films, a model system with strong electronic coupling. My results indicate that a multiexciton state forms within 40 fs of photoexcitation and loses singlet character on a 280 fs timescale, creating two triplet excitons. This is concordant with the transient absorption spectra of hexacene single crystals and definitively proves that exciton fission in hexacene proceeds through a multiexciton state. This state is likely common to all strongly-coupled systems and my results suggest that a reassessment of the generally-accepted singlet fission mechanism is required. Charge separation is the process of splitting neutral excitons into carriers that occurs at donor-acceptor heterojunctions in organic solar cells. Although this process is essential for device functionality, there are few compelling explanations for why it is highly efficient in certain organic photovoltaic systems. To investigate the charge separation process, I used the model system of charge transfer excitons at hexacene surfaces and time-resolved two-photon photoemission. Charge transfer excitons with sufficient energy spontaneously delocalize, growing from about 14 nm to over 50 nm within 200 fs. Entropy drives this delocalization, as the density of states within the Coulomb potential increases significantly with energy. This charge separation mechanism should occur at all donor-acceptor interfaces. My results show that entropy facilitates charge separation and indicate that the density of acceptor states should be a design consideration when constructing organic solar cells. Excited state chemistry Solar cells--Technological innovations Solar cells--Design and construction Picosecond pulses Exciton theory Chemistry, Physical and theoretical Condensed matter
97	Ground and Excited State Aromaticity : Design Tools for π-Conjugated Functional Molecules and Materials Dahlstrand, Christian January 2012 (has links) The main focus of this thesis is on the aromaticity of the ground state and electronically excited states of π-conjugated molecules and polymers, as well as how aromaticity is connected to their properties. The electronic structures of polybenzenoid hydrocarbons (PBHs) were explored through density functional theory (DFT) calculations and the π-component of the electron localization function (ELFπ). The study revealed how the π-electronic structure is influenced by the fusion of double bonds or benzene rings to the PBHs. We also demonstrated that the π-electrons of benzene extend to accommodate as much aromaticity as possible when bond length distorted. The aromatic chameleon property displayed by fulvenes, isobenzofulvenes, fulvalenes, bis(fulvene)s, and polyfulvenes were investigated using DFT calculations. The tria-, penta-, and heptafulvenes were shown to possess ionization energies and electron affinities which can be tuned extensively by substitution, some of which even outperform TTF and TCNQ, the prototypical electron donor and acceptor, respectively. The singlet-triplet energy gap of pentafulvenes can be tuned extensively by substitution to the point that the triplet state is lower than the singlet state and thus becomes the ground state. The ELFπ of isobenzofulvene shows that the benzene ring in an electronically excited state can be more aromatic than the corresponding ring in the ground state. We have shown that the 6-ring of [5.6.7]quinarene is influenced by a Hückel aromatic resonance structure with 4n+2 π-electrons in the excited quintet state. The bis(fulvene)s which are composed of a donor type heptafulvene and an acceptor type pentafulvene, retain the basic donor-acceptor properties of the two fragments and could function as compact donor-acceptor dyads. A few of the designed polyfulvenes were found to have band gaps below 1 eV at the PBC-B3LYP/6-31G(d) level. Various 2,7-disubstituted fluorenones and dibenzofulvenes were synthesized and their excited state properties were investigated by absorption spectroscopy and time-dependent DFT calculations. It was found that the 1A → 1B transition of ππ* character can be tuned by substitution in the 2,7-positions. The 2,7-bis(N,N-dimethyl) derivatives of fluorenone and dibenzofulvene displayed low energy transitions at 2.18 and 1.61 eV, respectively, in toluene. fulvene fulvalene polyfulvene aromaticity triplet state excited state Clar structure polybenzenoid hydrocarbons (PBH) conjugated polymers computational chemistry optical spectroscopy
98	Synthesis of Biomimetic Systems for Proton and Electron Transfer Reactions in the Ground and Excited State Parada, Giovanny A. January 2015 (has links) A detailed understanding of natural photosynthesis provides inspiration for the development of sustainable and renewable energy sources, i.e. a technology that is capable of converting solar energy directly into chemical fuels. This concept is called artificial photosynthesis. The work described in this thesis contains contributions to the development of artificial photosynthesis in two separate areas. The first one relates to light harvesting with a focus on the question of how electronic properties of photosensitizers can be tuned to allow for efficient photo-induced electron transfer processes. The study is based on a series of bis(tridentate)ruthenium(II) polypyridyl complexes, the geometric properties of which make them highly appealing for the construction of linear donor-photosensitizer-acceptor arrangements for efficient vectorial photo-induced electron transfer reactions. The chromophores possess remarkably long lived 3MLCT excited states and it is shown that their excited-state oxidation strength can be altered by variations of the ligand scaffold over a remarkably large range of 900 mV. The second area of relevance to natural and artificial photosynthesis that is discussed in this thesis relates to the coupled movement of protons and electrons. The delicate interplay between these two charged particles regulates thermodynamic and kinetic aspects in many key elementary steps of natural photosynthesis, and further studies are needed to fully understand this concept. The studies are based on redox active phenols with intramolecular hydrogen bonds to quinolines. The compounds thus bear a strong resemblance to the tyrosine/histidine couple in photosystem II, i.e. the water-plastoquinone oxidoreductase enzyme in photosynthesis. The design of the biomimetic models is such that the distance between the proton donor and acceptor is varied, enabling studies on the effect the proton transfer distance has on the rate of proton-coupled electron transfer reactions. The results of the studies have implications for the development of artificial photosynthesis, in particular in connection with redox leveling, charge accumulation, as well as electron and proton transfer. In addition to these two contributions, the excited-state dynamics of the intramolecular hydrogen-bonded phenols was investigated, thereby revealing design principles for technological applications based on excited-state intramolecular proton transfer and photoinduced tautomerization. Solar energy conversion artificial photosynthesis hydrogen bonds tautomerization proton-coupled electron transfer photosensitizer ruthenium complex.
99	Photochemical and photophysical studies of Excited State Intramolecular Proton Transfer (ESIPT) in biphenyl compounds Behin Aein, Niloufar 12 August 2010 (has links) This Thesis aims to examine the effects of substituents on the adjacent proton accepting phenyl ring with respect to a new type of excited state intramolecular proton transfer (ESIPT) process discovered by Wan and co-workers. Therefore, a number of 2-phenylphenols 23-28 were synthesized with electron-donor and electron-acceptor substituents such as methyl, methoxy, and ketone moieties on the adjacent proton accepting phenyl ring. The results obtained from examination of photochemical deuterium exchange showed that all derivatives except for ketone 27 underwent deuterium exchange (Фex = 0.019 - 0.079), primarily at the 2’-position on photolysis in D2O-CH3CN. In general, compounds with methoxy moiety (ies) on the adjacent proton accepting ring showed higher deuterium exchange yields. Diol 28 has the potential to undergo photosolvolysis as well as ESIPT process since it has both a benzyl alcohol and a phenol chromophore on the same molecule. Irradiation of 28 in 1:1 H2O-CH3OH gave the corresponding methyl ether product in high yield. Photolysis of 28 in 1:1 D2O-CH3OH also showed that ESIPT competes very well with photosolvolysis. Thus, this work has established that ESIPT can compete efficiently with photosolvolysis. Semi-empirical AM1 (examination of HOMOs and LUMOs) calculations show a large degree of charge transfer in the electronic excited state (except 27), from the phenol ring to the attached phenyl ring of the studied compounds. The AM1 calculation for ketone 27 showed that the carbonyl oxygen is more basic than the carbon atoms of the benzene ring, which explains the lack of deuterium exchange observed for 27. Photosolvolysis Biphenyl quinone methide
100	Pressure Effects on Electric Field Spectra of Molecular Rydberg States Altenloh, Daniel Dean 12 1900 (has links) Electric field studies, electrochromism, were used to obtain excited-state data for analogous divalent sulfur compounds. The sulfides investigated were dimethyl sulfide and small cyclic sulfides including the three to six member ring compounds. The excited-state dipole moments and polarizabilities are reported for the first s, p, and d Rydberg absorption bands which occur in the near vacuum ultraviolet region from 230 to 170 nm. The excited-state data are interpreted in terms of the particular excited-state (s, p, or d) for the molecules and the bending differences due to the presence of the ring and the number of atoms in the ring. The next section describes the use of electrochromism to investigate the pressure effect of argon, carbon tetrafluoride and sulfur hexafluoride on the spectra for molecular Rydberg states. electrochromism electric field studies Rydberg states cyclic sulfides dimethyl sulfides Molecular spectra. Sulfur compounds. Dipole moments. Excited state chemistry.

Search results