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1	Calculations of low energy electron-impact excitation cross sections of diatomic molecules by the close-coupling, R-matrix, and polarized-orbital methods Holley, Thomas Kennedy. January 1982 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1982. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 100-102). Electronic excitation.
2	Electron impact excitation of potassium and sodium Phelps, James Orson. January 1981 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1981. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 210-216). Electronic excitation. Potassium Sodium
3	Relaxation of excited electronic states in metal complexes Targos, William Michael, 1942- January 1966 (has links) No description available. Metal complexes. Electronic excitation. Luminescence.
4	Electron excitation cross sections of the 2p⁵3s levels of neon Phillips, Mark Howard. January 1982 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1982. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 129-1390).
5	Generation of high frequency electromagnetic waves by means of diamagnetic resonance and other excitation phenomena : study of electron beam instabilities in a magnetic field Lazarus, M. J. January 1964 (has links) No description available.
6	Theoretical Studies Of Electronic Excitation Energy Transfer Involving Some Nanomaterials Swathi, R S 05 1900 (has links) (PDF) Electronic Excitation Energy Transfer is an important intermolecular photophysical process that can affect the excited state lifetime of a chromophore. A molecule in an electronically excited state can return to the ground state by radiative as well as non-radiative processes. During the excited state lifetime, if the chromophore (energy donor) finds a suitable species (energy acceptor) nearby with resonant energy levels, it can transfer the excitation energy to that species and return to the ground state. This process is called Electronic Excitation Energy Transfer. When the energy donor is fluorescent, the process is called Fluorescence Resonance Energy Transfer (FRET) [1]. FRET is a non-radiative process that affects the fluorescence intensity as well as the excited state lifetime of the donor. It occurs due to the electrostatic coulombic interaction between the transition charge densities of the donor and the acceptor. The rate of energy transfer can be evaluated using the Fermi golden rule of quantum mechanics [2]. When the donor and the acceptor are separated by distances that are much larger in comparison with the sizes of the donor and the acceptor, the interaction between them can be thought of as that between their transition dipoles. In such a case, the interaction between the donor and the acceptor is dipolar and the rate of energy transfer has an R−6 dependence, where R is the distance between the donor and the acceptor [3]. This dependence has first been suggested theoretically by Forster in 1947 [4] followed by the experimental veriﬁcation by Stryer and Haugland [5]. Since then the process has been used as a spectroscopic ruler to study the conformational dynamics of biopolymers like DNA, RNA, proteins etc [6]. A variety of dye molecules have been explored for donors and acceptors in FRET and the range of distances that can be measured using FRET involving dyes is in the range 1 − 10 nm. When the distances between the donor and the acceptor are not much larger in comparison with their sizes, the dipolar approximation to the interaction is not a very good approximation, thereby leading to deviations from the traditional R-6 dependence. Such non-R-6dependencies are found for polymers, quantum wells, quantum wires etc [7–9]. The interest in such dependencies is due to the need for developing nanoscopic rulers that can measure distances well beyond 10 nm. The objective of our work has been to study energy transfer from fluorophores to various kinds of acceptors that have extended charge densities and understand the distance dependence of the rate of energy transfer [10]. We use the Fermi golden rule as the starting point and develop analytical models for evaluating the rate as a function of the distance between the donor and the acceptor. We study the process of energy transfer from fluorescent dye molecules that serve as energy donors to a variety of energy acceptors namely, graphene, doped graphene, single-walled carbon nanotubes and metal nanoparticles. We also study transfer from fluorophores to a semiconducting sheet and a semiconducting tube of electronic charge density. There have been experimental studies in the literature of the fluorescence quenching of dyes near single-walled carbon nanotubes [11–13]. But, there are no studies of the distance dependence of rate. Single-walled carbon nanotubes can be thought of as rolled up sheets of graphene. However, interestingly, there were no reports of fluorescence quenching by graphene at the time when we thought of this possibility. Therefore, we first study the process of energy transfer from a ﬂuorophore, which is kept at a distance z above a layer of graphene to the electronic energy levels of graphene. We ﬁnd that the long range behavior of the rate has an z -4 dependence on the distance [14, 15]. From our study of transfer from pyrene to graphene, we find that fluorescence quenching can be experimentally observed up to a distance of ~ 30 nm, which is quite large in comparison with the traditional FRET limit (10 nm). Recent experiments that have been performed after our theory was reported have in fact observed the fluorescence quenching of dyes near graphene. Further, the process has been found to be very useful in fabricating devices based on graphene [16], in eliminating fluorescence signals in resonance Raman spectroscopy [17] and in visualizing graphene based sheets using fluorescence quenching microscopy [18]. The process has also been found to be useful in quantitative DNA analysis [19, 20]. We study the transfer of an amount of energy hΩ from a dye molecule to doped graphene [21]. We consider the shift of the Fermi level from the K-point into the conduction band of graphene as a result of doping and evaluate the rate of transfer. We find a crossover of the distance dependence of the rate from z -4 to exponential as the Fermi level is increasingly shifted into the conduction band, with the crossover occurring at a shift of the Fermi level by an amount hΩ/2. We study the process of transfer of excitation energy from a fluorophore kept at a distance d away from the surface of a carbon nanotube to the electronic energy levels of the nanotube. We find both exponential and d−5 behavior of the rate [22]. For the case of metallic nanotubes, when the emission energy of the fluorophore is less than a threshold, the dependence is exponential. Otherwise, it is d−5 . For the case of semiconducting nanotubes, we ﬁnd that the rate follows an exponential dependence if the amount of energy that is transferred can cause only the excitonic transition of the tube. However, if any other band gap transition is allowed, the rate follows a d−5 dependence. For the case of transfer from pyrene to a (6, 4) nanotube, we ﬁnd that energy transfer is appreciable up to a distance of ~ 17 nm. We then study the process of energy transfer from a ﬂuorophore to a semiconducting sheet of electronic charge density [10]. We ﬁnd that the rate has an z-4 dependence. For the case of transfer to a semiconducting tube, we ﬁnd that the rate has a d -5dependence. The dependencies are in agreement with those obtained for graphene and carbon nanotubes respectively. This shows that the asymptotic distance dependencies are a consequence of the dimensionality of the transition charge densities and are robust. Strouse et al. [23, 24] have studied the process of energy transfer from the dye ﬂuorescein to a 1.4 nm diameter gold nanoparticle. Double-stranded DNA molecules of various lengths were used to ﬁx the distances between the donor and the acceptor. The rate was found to have a d-4distance dependence. They refer to this process as Nanoparticle Surface Energy Transfer (NSET) and the range of distances that can be measured using NSET is more than double that of the traditional FRET experiments. However, theoretical studies that consider the transfer to the plasmonic modes of the nanoparticle ﬁnd a predominant R-6 dependence [25]. We study the process of energy transfer from the dye ﬂuorescein to a 1.4 nm diameter gold nanoparticle considering the excitation of plasmons as well as electron-hole pairs of the nanoparticle [26]. We find that the rate follows the usual Forster type R−6 distance dependence at large distances. But, at short distances, there are contributions of the form R−-n with n > 6. This is due to the quadrupolar and octupolar modes of excitation of the nanoparticle, the rates corresponding to which have R-8 and R−-10 dependencies respectively. Recent calculations using DFT also find similar deviations at short distances [27]. Nanomaterials - Electronic Excitation Electronic Excitation Theory Electronic Excitation Energy Transfer Fluorescence Resonance Energy Transfer Graphene Resonance Energy Transfer Nanotechnology
7	Bond selective electronic excitation and short-time photodissociation dynamics of dihalomethanes from resonance raman spectroscopy / Kwok, Wai-ming. January 1997 (has links) Thesis (Ph. D.)--University of Hong Kong, 1997. / Includes bibliographical references.
8	Ultrafast lattice dynamics in excitonic self-trapping of quasi-one dimensional materials Morrissey, Francis Xavier, January 2007 (has links) (PDF) Thesis (Ph. D.)--Washington State University, May 2007. / Includes bibliographical references.
9	THE VIBRATIONAL AND ELECTRONIC ABSORPTION SPECTRA OF SILVER-LITHIUM, SILVER-SODIUM, COPPER-LITHIUM, AND COPPER-SODIUM FROM SINGLE MOLECULES TO SMALL PARTICLES. PFLIBSEN, KENT PAUL. January 1984 (has links) Vibrational and electronic absorption spectra of metal alloy molecules and small particles have been measured. The matrix isolation technique was used to produce the samples. Dissimilar metals were combined to provide far infrared vibrational activity. Through the study of the electronic and vibrational excitation spectra, metallic interatomic binding potential characteristics could be investigated. The absorption spectra of the molecular systems were modelled using the extended Hueckel method, for the electronic excitations, and a dynamical matrix-normal mode technique for the vibrational excitations. Surface plasmon absorption, from the metal alloy particles, could not be measured but surface phonon absorption was measured. Electronic and vibrational absorption lines in alloyed metal molecules were measured and compared to the calculations. A surface diffusion model was developed to explain the dependences of molecule and particle size on the experimentally controlled system parameters. Copper -- Spectra. Electronic excitation. Silver -- Spectra. Infrared spectroscopy.
10	Bond selective electronic excitation and short-time photodissociation dynamics of dihalomethanes from resonance raman spectroscopy 郭偉明, Kwok, Wai-ming. January 1997 (has links) published_or_final_version / Chemistry / Doctoral / Doctor of Philosophy Methane - Molecular aspects. Electronic excitation. Dissociation. Raman spectroscopy.

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