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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Excited states and vibrational spectroscopy of ice and adsorbed biomolecules

Crowell, Vernon Dewayne 12 January 2015 (has links)
The photodesorption of water molecules from amorphous solid water (ASW) by 157-nm irradiation has been examined using resonance-enhanced multiphoton ionization (REMPI). The rotational temperature has been determined, by comparison with simulations, to be 425 ± 75 K. The time-of-flight (TOF) spectrum of H2O (v = 0) has been fit with a Maxwell-Boltzmann distribution with a translational temperatures of 700 ± 200 K (0.12 ± 0.03 eV). H+ and OH+ fragment ions have been detected with non-resonant multiphoton ionization, indicating vibrationally excited parent water molecules with translational energies of 0.24 ± 0.08 eV. The cross section for water removal from ASW by 7.9-eV photons near 100 K is (6.9 ± 1.8) x 10-20 cm2 for > 10 L H2O exposure. Electronic structure computations have also probed the excited states of water and the mechanisms of desorption. Calculated electron attachment and detachment densities show that exciton delocalization leads to a dipole reversal state in the first singlet excited state of a model system of hexagonal water ice. Ab Initio Molecular Dynamics (AIMD) simulations show possible desorption of a photo-excited water molecule from this cluster, though the non-hydrogen bonded OH bond is stretched significantly before desorption. Potential energy curves of this OH stretch in the electronic excited state show a barrier to dissociation, lending credence to the dipole reversal mechanism.
2

Time-Resolved Spectroscopy of Bare and Reacted Gold and Silver Clusters Materials for New Photochemistry? /

Niemietz, Marco. January 2007 (has links)
Konstanz, Univ., Diss., 2007.
3

Vibrationally enhanced associative photodesorption of H2 (D2) from Ru(0001) : quantum and classical approaches

Vazhappilly, Tijo Joseph January 2008 (has links)
Nowadays, reactions on surfaces are attaining great scientific interest because of their diverse applications. Some well known examples are production of ammonia on metal surfaces for fertilizers and reduction of poisonous gases from automobiles using catalytic converters. More recently, also photoinduced reactions at surfaces, useful, textit{e.g.}, for photocatalysis, were studied in detail. Often, very short laser pulses are used for this purpose. Some of these reactions are occurring on femtosecond (1 fs=$10^{-15}$ s) time scales since the motion of atoms (which leads to bond breaking and new bond formation) belongs to this time range. This thesis investigates the femtosecond laser induced associative photodesorption of hydrogen, H$_2$, and deuterium, D$_2$, from a ruthenium metal surface. Many interesting features of this reaction were explored by experimentalists: (i) a huge isotope effect in the desorption probability of H$_2$ and D$_2$, (ii) the desorption yield increases non-linearly with the applied visible (vis) laser fluence, and (iii) unequal energy partitioning to different degrees of freedom. These peculiarities are due to the fact that an ultrashort vis pulse creates hot electrons in the metal. These hot electrons then transfer energy to adsorbate vibrations which leads to desorption. In fact, adsorbate vibrations are strongly coupled to metal electrons, textit{i.e.}, through non-adiabatic couplings. This means that, surfaces introduce additional channels for energy exchange which makes the control of surface reactions more difficult than the control of reactions in the gas phase. In fact, the quantum yield of surface photochemical reactions is often notoriously small. One of the goals of the present thesis is to suggest, on the basis of theoretical simulations, strategies to control/enhance the photodesorption yield of H$_2$ and D$_2$ from Ru(0001). For this purpose, we suggest a textit{hybrid scheme} to control the reaction, where the adsorbate vibrations are initially excited by an infrared (IR) pulse, prior to the vis pulse. Both textit{adiabatic} and textit{non-adiabatic} representations for photoinduced desorption problems are employed here. The textit{adiabatic} representation is realized within the classical picture using Molecular Dynamics (MD) with electronic frictions. In a quantum mechanical description, textit{non-adiabatic} representations are employed within open-system density matrix theory. The time evolution of the desorption process is studied using a two-mode reduced dimensionality model with one vibrational coordinate and one translational coordinate of the adsorbate. The ground and excited electronic state potentials, and dipole function for the IR excitation are taken from first principles. The IR driven vibrational excitation of adsorbate modes with moderate efficiency is achieved by (modified) $pi$-pulses or/and optimal control theory. The fluence dependence of the desorption reaction is computed by including the electronic temperature of the metal calculated from the two-temperature model. Here, our theoretical results show a good agreement with experimental and previous theoretical findings. We then employed the IR+vis strategy in both models. Here, we found that vibrational excitation indeed promotes the desorption of hydrogen and deuterium. To summarize, we conclude that photocontrol of this surface reaction can be achieved by our IR+vis scheme. / Heutzutage werden Reaktionen auf Oberflächen wegen ihrer vielfältigen Anwendungen intensiv untersucht. Einige der bekannten Beispiele sind die Herstellung von Ammoniak auf Metalloberflächen für die Kunstdüngerproduktion und die Reduktion giftiger Abgase in Autokatalysatoren. In letzter Zeit wurden auch photoinduzierte Reaktionen an Oberflächen eingehender untersucht, die z.B. für die Photokatalyse verwandt werden können. Häufig werden in diesen Untersuchungen sehr kurze Laserpulse benutzt. Einige der Reaktionen finden auf einer Femtosekunden-Zeitskala mbox{(1 fs =10$^{-15}$ s)} statt, da die Bewegungen einzelner Atome in derart kurzen Zeitspannen ablaufen (durch die der Bindungsbruch und das Knüpfen neuer Bindungen verursacht wird). Diese Arbeit untersucht die femtosekunden-laserinduzierte assoziative Photodesorption von Wasserstoff, H$_2$, und Deuterium, D$_2$, von einer Rutheniumoberfläche. Viele interessante Eigenschaften dieser Reaktion wurden in Experimenten entdeckt: (i) ein großer Isotopeneffekt in der Desorptionswahrscheinlichkeit von H$_2$ und D$_2$, (ii) die Desorptionsausbeute steigt nicht-linear mit der (vis) Laserfluenz an und (iii) eine Nicht-Gleichverteilung der Energie auf die einzelnen Freiheitsgrade. Diese Auffälligkeiten sind durch den Umstand verursacht, dass der ultrakurze vis-Laserpuls heiße Elektronen im Metall erzeugt. Die heißen Elektronen transferieren dann Energie in die Schwingungen des Adsorbats, was zur Desorption führt. Tatsächlich sind die Adsorbatschwingungen stark an die Elektronen gekoppelt, nämlich durch nicht-adiabatische Kopplungen. Dies bedeutet, dass durch Oberflächen neue Kanäle für den Energietransfer geöffnet werden, was die Kontrolle von Oberflächenreaktionen im Vergleich zu solchen in der Gasphase erschwert. In der Tat sind die Quantenausbeuten von photochemischen Oberflächenreaktionen bekannterweise klein. Eines der Ziele in der vorliegenden Arbeit ist es auf der Basis von theoretischen Simulationen Strategien vorzuschlagen, um die Photodesorptionsausbeute von H$_2$ und D$_2$ von Ru(0001) zu kontrollieren bzw. zu verbessern. Zu diesem Zweck schlagen wir ein gemischtes Kontrollschema für die Reaktion vor, bei dem zunächst die Adsorbatschwingungen vor dem vis-Puls durch einen infraroten (IR) Puls angeregt werden. Sowohl adiabatische als auch nicht-adiabatische Repräsentationen für photoinduzierte Desorptionsprozesse werden dabei benutzt. Die adiabatische Repräsentation ist in klassischen Molekulardynamik-Simulationen mit elektronischer Reibung verwirklicht. In einer quantenmechanischen Beschreibung werden nicht-adiabatische Repräsentationen innerhalb der Dichtematrixtheorie für offene Quantensysteme verwandt. Die zeitliche Entwicklung des Desorptionsprozesses wird in einem Zwei-Modenmodell reduzierter Dimensionalität mit einer Schwingungs- und einer Translationskoordinate des Adsorbats beschrieben. Die Potentiale für den elektronische Grundzustand und den angeregten Zustand sind abgeleitet aus quantenchemischen Rechnungen (textsl{first principles}). Die IR-getriebene Schwingungsanregung der Adsorbatmoden mit moderatem Wirkungsgrad wird mit (modifizierten) $pi$-Pulsen und/oder der Theorie der optimalen Kontrolle erreicht. Die Abhängigkeit der Desorption von der Fluenz wird mit Hilfe der elektronischen Temperatur des Metalls berechnet, welche im Rahmen des Zwei-Temperatur-Modells bestimmt wird. Dabei weisen unsere Ergebnisse eine gute Übereinstimmung mit experimentellen und früheren theoretischen Arbeiten auf. Daraufhin wandten wir die IR+vis Strategie in beiden Modellen an. Dadurch konnten wir zeigen, dass Schwingungsanregung in der Tat die Desorption von Wasserstoff und Deuterium begünstigt. Zusammenfassend stellen wir fest, dass die Photokontrolle dieser Oberflächenreaktion durch unser IR+vis Schema erreichbar ist.
4

Novel III-Nitride growth by ultraviolet radiation assisted metal organic molecular beam epitaxy

Pritchett, David Chu 12 February 2009 (has links)
While modern epitaxial methods enable precise, monolayer (ML) control of the thin film deposition process, the complexity of certain device structures is ultimately limited by the capability and cost of the fabrication process. The objective of this work is to develop a pathway toward three-dimensional epitaxy (3DE) - the ability to intentionally and dynamically pattern regions of a film during the deposition process - in order to enable novel device concepts unbound by the traditional device fabrication paradigm. This work pioneers UV-assisted metal organic molecular beam epitaxy (MOMBE) as a particularly selective epitaxy technique to create a pathway toward 3DE of a crucial and topical material system - the III-Nitrides. A novel UV-assisted MOMBE system is developed enabling intense UV irradiation of films during growth. High quality, heavily (unintentionally) carbon-doped GaN is successfully grown by NH₃-based MOMBE and for the first time InGaN, AlGaN, and magnesium-doped GaN are demonstrated by NH₃-based MOMBE. Intense UV irradiation of films during NH₃-based MOMBE significantly enhances photo-desorption of species during the growth process, subsequently affecting the resultant InGaN alloy composition, carbon dopant concentration, or magnesium dopant concentration. A digital micromirror device is introduced to pattern incident UV radiation during InGaN growth, demonstrating that the effects of photoexcitation during MOMBE which have been proposed, discovered, and identified by this thesis indeed can be leveraged to deposit an InGaN film that is compositionally patterned within the growth plane. The results demonstrate that the new approach presented herein is possible for the 3DE of III-Nitrides if additional challenges in practical implementation can be overcome.

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