Global ETD Search

51	Improvements in excitation selectivity and spectral precision in Fourier transform NMR and mass spectrometry / Chen, Ling January 1987 (has links) No description available. Chemistry Fourier transform spectroscopy Mass spectrometry Excited state chemistry
52	Modification of Excited State Behavior with Ligand Substitution in Ru(II),Rh(III) Bimetallic Supramolecular Complexes Sayre, Hannah Joy 03 September 2015 (has links) The terminal ligand in [(Ph₂phen)₂Ru(dpp)RhCl₂(TL)](PF₆)₃ (Ph2phen = 4,7-diphenyl1,10-phenanthroline; dpp = 2,3-bis(2-pyridyl)pyrazine; TL = terminal ligand – a 4,4′-disubstituted-2,2′-bipyridine where the substituent was carbomethoxy (dcmbpy), hydrogen (bpy) or methyl (Me₂bpy)). The electron-withdrawing ability of the substituent was shown to increase the rate of chloride loss upon electrochemical reduction, facilitating catalytic water reduction. The electronic properties of the terminal ligand also impact the photophysical properties of the molecule. The excited state lifetime of the complex with a dcmbpy terminal ligand was 93 ns while the excited state lifetimes of the complexes with a bpy or Me₂bpy terminal ligand were 44 ns and 47 ns, respectively. Ligand substitution was shown to influence the photocatalytic water reduction activity of these complexes with the dcmbpy complex producing approximately twice the amount of hydrogen (62 ± 7 turnovers in 20 h) as the other two complexes. / Master of Science supramolecule photochemistry electron-withdrawing excited state lifetime water reduction
53	Evaluation of potential photodynamic therapy agents and patient-relevant biomarker combinations for the selective targeting of cancer Rodriguez Corrales, Jose Angel 21 August 2018 (has links) Cancer, the second leading cause of death worldwide, is characterized by uncontrolled and abnormal cell growth. Even though researchers have made significant progress in its treatment over the past several decades, innovative therapeutic approaches that both improve patient survival and lessen the many debilitating side effects of conventional cancer treatments are vital. Accordingly, we first investigated the mechanism of interaction of a bimetallic complex, Ru(II)-Rh(III), with DNA. Non-covalent binding of Ru(II)-Rh(III) is strong and involves electrostatic and, potentially, groove binding interactions. Ru(II)-Rh(III) photobinds and photocleaves DNA through an O2-independent, metal-center mediated mechanism that could be beneficial in hypoxic tumors. Furthermore, the extent of covalent binding and cleavage of DNA, which inhibit PCR amplification, is dependent upon the strength of the non-covalent interactions. These results suggest that the toxicity of Ru(II)-Rh(III) could be selectively generated in tissues irradiated with light (e.g., a tumor). Secondly, we identified protein combinations selectively present in melanoma, which could be utilized in heteromultivalency. Heteromultivalent scaffolds display higher affinity towards cells that express a protein combination in comparison to those with only one of the proteins, which facilitates cell discrimination. Using an empirically-optimized threshold-based screening method and expression profiles of melanoma patients and normal tissues, we identified surface proteins and protein combinations that are selectively found in melanoma patients and not in normal tissues. After a preliminary validation process using the scientific literature, we used immunofluorescence to confirm differential expression of some of these combinations in established melanoma cell lines in comparison to immortalized keratinocytes controls. Finally, we investigated the resazurin assay, a method used for the evaluation of proliferation and cytotoxicity in more than 2,000 publications. We found that only ~14% of these utilized validated assay conditions, while ~40% failed to report essential analytical parameters needed for their replication. We evaluated assay parameters needed for accurate estimation of cell number in eight cell lines, and found that these are highly variable and independent of tissue type, growth kinetics, and energetic parameters. Furthermore, we obtained some insights into the biochemical reduction of resazurin and proposed minimum reporting standards, along with a sample protocol for assay validation. / PHD / Cancer, a group of diseases characterized by uncontrolled and abnormal cell growth, is the second-leading cause of death worldwide. Even though researchers have made significant progress in its treatment over the past several decades, innovative therapeutic approaches that both improve survival outcome and lessen the many debilitating side-effects of conventional cancer treatments are vital. First, we investigated the mechanism of interaction of a particular molecule, Ru(II)- Rh(III), with DNA. We found that Ru(II)-Rh(III) is strongly attracted to DNA due to its charge and an interaction with the indentations along its helix. Upon light activation only, Ru(II)-Rh(III) binds to and cleaves DNA without the need for molecular oxygen, which is scarce in tumors and can limit the activity of other drugs, and to an extent that is affected by the concentration of ions in the solution. Thus, the cytotoxic effect of Ru(II)-Rh(III) might be selectively activated in those tissues that are irradiated with light (e.g., a tumor). Secondly, we identified protein combinations selectively present in melanoma, which could be utilized in heteromultivalency. Heteromultivalent scaffolds bind strongly to cells that express a combination of proteins rather than one protein at a time, making them excellent candidates for delivering a payload in a selective manner. Using expression profiles of melanoma and normal tissues, we identified surface proteins and protein combinations that are selectively found in melanoma patients and not in normal tissues. After a preliminary validation process using the scientific literature, we used confirmed differences in the expression intensities of some of these combinations in melanoma cell lines in comparison to normal skin controls. Finally, we investigated the resazurin assay, a method used for the evaluation of cell growth and drug candidates in more than 2,000 publications. We found that only ~14% of these utilized validated assay conditions, while ~40% failed to report essential analytical parameters needed for their replication. We evaluated assay conditions for eight cell lines, and found that these are highly variable and independent of tissue type and some metabolic parameters. Furthermore, we obtained insights into the mechanism through which cells react with resazurin and proposed minimum reporting standards for publications, along with a protocol for assay validation. photodynamic therapy excited state reactivity DNA heteromultivalency melanoma cytotoxicity resazurin
54	Electric Dichroism Spectroscopy in the Vacuum Ultraviolet Causley, Gary C. 05 1900 (has links) When a molecule, which possess a permanent dipole moment is exposed to an intense electric field, its absorption spectrum may be altered. These alterations are manifest as shifts in energy and as changes in band shape and intensity. The electric dichroism of absorption bands can be used to probe the excited state that is formed when a molecule undergoes a transition. The properties that may be investigated include transition polarization, excited state dipole moment and mean polarizability, and field-induced mixing of symmetrically equivalent excited states. The theoretical model and experimental devices that have been developed to determine these properties are presented and discussed. The data, taken in total, and its combination with other existing evidence, adds credence to the assignment of the second excited singlet of aldehydes and ketones to be extravalent, accompanied by relatively large delocalization of electronic charge, and polarized in-planiie and perpendicularly to the C-0 axis. altered absorption spectrums excited state chemistry dipole moment electric dichroism spectroscopy Dichroism. Absorption spectra. Excited state chemistry.
55	Light Control using Organometallic Chromophores Henriksson, Johan January 2006 (has links) <p> </p><p>The interaction between light and organometallic chromophores has been investigated theoretically in a strive for fast optical filters. The main emphasis is on two-photon absorption and excited state absorption as illustrated in the Jablonski diagram. We stress the need for relativistic calculations and have developed methods to address this issue. Furthermore, we present how quantum chemical calculations can be combined with Maxwell's equations in order to simulate propagation of laser pulses through a materials doped with chromophores with high two-photon absorption cross sections. Finally, we also discuss how fast agile filters using spin-transition materials can be modeled in order to accomplish theoretical material design.</p> / Report code: LIU-TEK-LIC-2006:55. On the day of the defence date the status on article III was Manuscript, article IV was Accepted and article V was Submitted. organometallic chromophores two-photon absorption excited state absorption excited state dipole moment four-component formalism clamping levels spin-transition Computational physics Beräkningsfysik
56	Tuning of the Excited State Properties of Ruthenium(II)-Polypyridyl Complexes Abrahamsson, Maria January 2006 (has links) <p>Processes where a molecule absorbs visible light and then converts the solar energy into chemical energy are important in many biological systems, such as photosynthesis and also in many technical applications e.g. photovoltaics. This thesis describes a part of a multidisciplinary project, aiming at a functional mimic of the natural photosynthesis, with the overall goal of production of a renewable fuel from sun and water. More specific, the thesis is focused on design and photophysical characterization of new photosensitizers, i.e. light absorbers that should be capable of transferring electrons to an acceptor and be suitable building blocks for supramolecular rod-like donor-photosensitizer-acceptor arrays.</p><p>The excited state lifetime, the excited state energy and the geometry are important properties for a photosensitizer. The work presented here describes a new strategy to obtain longer excited state lifetimes of the geometrically favorable Ru(II)-bistridentate type complexes, without a concomitant substantial decrease in excited state energy. The basic idea is that a more octahedral coordination around the Ru will lead to longer excited state lifetimes. In the first generation of new photosensitizers a 50-fold increase of the excited state lifetime was observed, going from 0.25 ns for the model complex to 15 ns for the best photosensitizer. The second generation goes another step forward, to an excited state lifetime of 810 ns. Furthermore, the third generation of new photosensitizers show excited state lifetimes in the 0.45 - 5.5 microsecond region at room temperature, a significant improvement. In addition, the third generation of photosensitizers are suitable for further symmetric attachment of electron donor and acceptor motifs, and it is shown that the favorable properties are maintained upon the attachment of anchoring groups. The reactivity of the excited state towards light-induced reactions is proved and the photostability is sufficient so the new design strategy has proven successful.</p> Physical chemistry Artificial photosynthesis Ruthenium(II) Bistridentate complexes Excited state lifetime Temperature dependence Excited state decay Fysikalisk kemi
57	Light Control using Organometallic Chromophores Henriksson, Johan January 2006 (has links) The interaction between light and organometallic chromophores has been investigated theoretically in a strive for fast optical filters. The main emphasis is on two-photon absorption and excited state absorption as illustrated in the Jablonski diagram. We stress the need for relativistic calculations and have developed methods to address this issue. Furthermore, we present how quantum chemical calculations can be combined with Maxwell's equations in order to simulate propagation of laser pulses through a materials doped with chromophores with high two-photon absorption cross sections. Finally, we also discuss how fast agile filters using spin-transition materials can be modeled in order to accomplish theoretical material design. / <p>Report code: LIU-TEK-LIC-2006:55. On the day of the defence date the status on article III was Manuscript, article IV was Accepted and article V was Submitted.</p> organometallic chromophores two-photon absorption excited state absorption excited state dipole moment four-component formalism clamping levels spin-transition Computational physics Beräkningsfysik
58	N-methyl-6-hydroxyquinolinium: an investigation into the spectroscopy and applications of excited-state proton transfer Salvitti, Michael Anthony 11 July 2008 (has links) N-methyl-6-hydroxyquinolinium (NM6HQ) is a powerful excited-state proton donor, exhibiting a huge pKa drop from 7.2 in the ground state to -7 in the excited state. The zwitterionic nature of the proton transfer product encourages intramolecular electron transfer away from the hydroxyl moiety to the distal ring, allowing for a large pKa jump in the excited state. This process is reversible, making the NM6HQ salts powerful transient superacids. We have investigated the excited-state proton transfer (ESPT) from NM6HQ salts to various basic solvents (alcohols, DMSO). A model has been developed that adequately describes the ion-dipole interactions in the ESPT geminate-recombination process. Our studies have shown that the counterion plays a large role in the ESPT. Likewise, initiation of cationic polymerization is controlled by the counterion. NM6HQ perfluoroalkylsulfonates appear to be the first molecules reported which are capable of initiating aliphatic epoxide polymerization at room temperature through a proton transfer mechanism. PTTS Proton transfer to solvent ESPT Excited-state proton transfer Proton transfer Counterion effects Photoacid generator PAG Anion effects Proton transfer reactions Excited state chemistry Photopolymerization Polymerization
59	Tuning of the Excited State Properties of Ruthenium(II)-Polypyridyl Complexes Abrahamsson, Maria January 2006 (has links) Processes where a molecule absorbs visible light and then converts the solar energy into chemical energy are important in many biological systems, such as photosynthesis and also in many technical applications e.g. photovoltaics. This thesis describes a part of a multidisciplinary project, aiming at a functional mimic of the natural photosynthesis, with the overall goal of production of a renewable fuel from sun and water. More specific, the thesis is focused on design and photophysical characterization of new photosensitizers, i.e. light absorbers that should be capable of transferring electrons to an acceptor and be suitable building blocks for supramolecular rod-like donor-photosensitizer-acceptor arrays. The excited state lifetime, the excited state energy and the geometry are important properties for a photosensitizer. The work presented here describes a new strategy to obtain longer excited state lifetimes of the geometrically favorable Ru(II)-bistridentate type complexes, without a concomitant substantial decrease in excited state energy. The basic idea is that a more octahedral coordination around the Ru will lead to longer excited state lifetimes. In the first generation of new photosensitizers a 50-fold increase of the excited state lifetime was observed, going from 0.25 ns for the model complex to 15 ns for the best photosensitizer. The second generation goes another step forward, to an excited state lifetime of 810 ns. Furthermore, the third generation of new photosensitizers show excited state lifetimes in the 0.45 - 5.5 microsecond region at room temperature, a significant improvement. In addition, the third generation of photosensitizers are suitable for further symmetric attachment of electron donor and acceptor motifs, and it is shown that the favorable properties are maintained upon the attachment of anchoring groups. The reactivity of the excited state towards light-induced reactions is proved and the photostability is sufficient so the new design strategy has proven successful. Physical chemistry Artificial photosynthesis Ruthenium(II) Bistridentate complexes Excited state lifetime Temperature dependence Excited state decay Fysikalisk kemi
60	Excited-state dynamics of small organic molecules studied by time-resolved photoelectron spectroscopy Geng, Ting January 2017 (has links) Ultra-violet and visible light induced processes in small organic molecules play very important roles in many fields, e.g., environmental sciences, biology, material development, chemistry, astrophysics and many others. Thus it is of great importance to better understand the mechanisms behind these processes. To achieve this, a bottom-up approach is most effective, where the photo-induced dynamics occurring in the simplest organic molecule (ethylene) are used as a starting point. Simple substituents and functional groups are added in a controlled manner to ethylene, and changes in the dynamics are investigated as a function of these modifications. In this manner, the dynamics occurring in more complex systems can be explored from a known base. In this thesis, the excited state dynamics of small organic molecules are studied by a combination of time-resolved photoelectron spectroscopy and various computational methods in order to determine the basic rules necessary to help understand and predict the dynamics of photo-induced processes. The dynamics occurring in ethylene involve a double bond torsion on the ππ* excited state, followed by the decay to the ground state coupled with pyramidalization and hydrogen migration. Several different routes of chemical modification are used as the basis to probe these dynamics as the molecular complexity is increased. (i) When ethylene is modified by the addition of an alkoxyl group (-OCnH2n+1), a new bond cleavage reaction is observed on the πσ* state. When modified by a cyano (-CN) group, a significant change in the carbon atom involved in pyramidalization is observed. (ii) When ethylene used to build up small cyclic polyenes, it is observed that the motifs of the ethylene dynamics persist, expressed as ring puckering and ring opening. (iii) In small heteroaromatic systems, i.e., an aromatic ring containing an ethylene-like sub-structure and one or two non-carbon atoms, the type of heteroatom (N: pyrrole, pyrazole O: furan) gives rise to different bond cleavage and ring puckering channels. Furthermore, adding an aldehyde group (-C=O) onto furan, as a way to lengthen the delocalised ring electron system, opens up additional reaction channels via a nπ* state. The results presented here are used to build up a more complete picture of the dynamics that occur in small molecular systems after they are excited by a visible or UV photon, and are used as a basis to motivate further investigations. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 5: Manuscript. Paper 6: Manuscript.</p> time-resolved photoelectron spectroscopy excited-state dynamics organic molecules Atom and Molecular Physics and Optics Atom- och molekylfysik och optik

Search results