Collisional Dynamic Elements of the Pyrazine - N2O System:Middle and Low J States

Mix, La Moyne Tyler

05 January 2014

Unimolecular reactions based on the Lindemann - Hinchelwood mechanism are important to understanding combustion and atmospheric processes. The main feature of this mechanism is the energy transfer probability distribution function, P(E',E). We have chosen to study P(E',E) through gas phase collisional dynamics probed with IR transient absorption spectroscopy. Post-collision absorption line widths for the pyrazine-N2O system are used to calculate lab frame translational temperatures. The translational temperatures reveal that collisions with large rotational energy transfer also transfer large amounts of translational energy. For J states >47 the relationship is linear indicating a constant impact parameter. Line widths for J=47 through J=59 also showed that there is no out-scattering from these states, in contrast to work performed previously in the Sevy group. The discrepancy between these measurements prompted a complete analysis of the causes of noise in the experimental system. Defective instruments were identified and noise sources localized, including IR diode frequency jitter. Improved experimental techniques and troubleshooting guides are explained for future researchers in the Sevy group.

Collisional Dynamics

Energy Transfer

IR Transient Absorbtion

Eric T. Sevy

LaMoyne Tyler Mix

Biochemistry

Chemistry

Characterization Of Composite Broad Band Absorbing Conjugated Polymer Nanoparticles Using Steady-state, Time-resolve And Single Particle Spectroscopy

Bonner, Maxwell Scotland

01 January 2011

As the global economy searches for reliable, inexpensive and environmentally friendly renewable energy resources, energy conservation by means of photovoltaics has seen near exponential growth in the last decade. Compared to state-of-the-art inorganic solar cells, organic photovoltaics (OPVs) composed of conjugated polymers are particularly interesting because of their processability, flexibility and the potential for large area devices at a reduced fabrication cost. It has been extensively documented that the interchain and intrachain interactions of conjugated polymers complicate the fundamental understanding of the optical and electronic properties in the solid-state (i.e. thin film active layer). These interactions are highly dependent on the nanoscale morphology of the solid-state material, leading to a heterogeneous morphology where individual conjugated polymer molecules obtain a variety of different optoelectronic properties. Therefore, it is of the utmost importance to fundamentally study conjugated polymer systems at the single molecule or nanoparticle level instead of the complex macroscopic bulk level. This dissertation research aims to develop simplified nanoparticle models that are representation of the nanodomains found in the solid-state material, while fundamentally addressing light harvesting, energy transfer and interfacial charge transfer mechanisms and their relationship to the electronic structure, material composition and morphology of the nanoparticle system. In preceding work, monofunctional doped nanoparticles (polymer-polymer) were fabricated with enhanced light harvesting and Fӧrster energy transfer properties by blending Poly[(o-phenylenevinylene)-alt-(2-methoxy-5-(2-ethylhexyloxy)-p-phenylenevinylene)] (BPPV) and Poly[2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene] (MEH-PPV) at various MEHPPV doping ratios. While single particle spectroscopy (SPS) reveals a broad distribution of v optoelectronic and photophysical properties, time-correlated single photon counting (TC-SPC) spectroscopy displays multiple fluorescence lifetime components for each nanoparticle composition, resulting from changing polymer chain morphologies and polymer-polymer aggregation. In addition, difunctional doped nanoparticles were fabricated by doping the monofunctional doped nanoparticles with PC60BM ([6,6]-phenyl-C61-butyric acid methyl ester) to investigate competition between intermolecular energy transfer and interfacial charge transfer. Specifically, the difunctional SPS data illustrated enhanced and reduced energy transfer mechanisms that are dependent on the material composition of MEH-PPV and PC60BM. These data are indicative of changes in inter- and intrachain interactions of BPPV and MEH-PPV and their respective nanoscale morphologies. Together, these fundamental studies provide a thorough understanding of monofunctional and difunctional doped nanoparticle photophysics, necessary for understanding the morphological, optoelectronic and photophysical processes that can limit the efficiency of OPVs and provide insight for strategies aimed at improving device efficiencies.

Conjugated polymers

Energy transfer

Nanoparticles

Spectrum analysis

Time resolved spectroscopy

Chemistry

Two-photon 3d Optical Data Storage Via Fluorescence Modulation Of Fluorene Dyes By Photochromic Diarylethenes

Corredor, Claudia

01 January 2007

Three-dimensional (3D) optical data storage based on two-photon processes provides highly confined excitation in a recording medium and a mechanism for writing and reading data with less cross talk between multiple memory layers, due to the quadratic dependence of two photon absorption (2PA) on the incident light intensity. The capacity for highly confined excitation and intrinsic 3D resolution affords immense information storage capacity (up to 1012 bits/cm3). Recently, the use of photochromic materials for 3D memory has received intense interest because of several major advantages over current optical systems, including their erasable/rewritable capability, high resolution, and high sensitivity. This work demonstrates a novel two-photon 3D optical storage system based on the modulation of the fluorescence emission of a highly efficient two-photon absorbing fluorescent dye (fluorene derivative) and a photochromic compound (diarylethene). The feasibility of using efficient intermolecular Förster Resonance Energy Transfer (RET) from the non-covalently linked two-photon absorbing fluorescent fluorene derivative to the photochromic diarylethene as a novel read-out method in a two-photon optical data storage system was explored. For the purpose of the development of this novel two-photon 3D optical storage system, linear and two-photon spectroscopic characterization of commercial diarylethenes in solution and in a polymer film and evidence of their cyclization (O→C) and cycloreversion (C→O) reactions induced by two-photon excitation were undertaken. For the development of a readout method, Resonance Energy Transfer (RET) from twophoton absorbing fluorene derivatives to photochromic compounds was investigated under one and two-photon excitation. The Förster's distances and critical acceptor concentrations were determined for non-bound donor-acceptor pairs in homogeneous molecular ensembles. To the best of my knowledge, modulation of the two-photon fluorescence emission of a dye by a photochromic diarylethene has not been reported as a mechanism to read the recorded information in a 3D optical data storage system. This system was demonstrated to be highly stable and suitable for recording data in thick storage media. The proposed RET-based readout method proved to be non-destructive (exhibiting a loss of the initial fluorescence emission less than 20% of the initial emission after 10,000 readout cycles). Potential application of this system in a rewritable-erasable optical data storage system was proved. As part of the strategy for the development of diarylethenes optimized for 3D optical data storage, derivatives containing Ï€-conjugated fluorene molecules were synthesized and characterized. The final part of this reasearch demonstrated the photostability of fluorine derivatives showing strong molecular polarizability and high fluorescence quantum yields. These compounds are quite promising for application in RET-based two-photon 3D optical data storage. Hence, the photostability of these fluorene derivatives is a key parameter to establish, and facilitates their full utility in critical applications.

diarylethenes

optical data storage

two-photon absorption

resonance energy transfer

photochromic materials

fluorene derivatives

Chemistry

Förster Resonance Energy Transfer in PbS Films

Leopold, Matthew

02 October 2014

No description available.

Physics

PbS

Quantum dot

dipcoating

hall effect

Investigation of Energy Transfer, Quantification, and Localization of Peptides and Proteins by Fluorescence Spectroscopy and Mass Spectrometry

Saraswat, Suraj

24 September 2012

No description available.

Chemistry

Mass Spectrometry

Fluorescence Spectroscopy

Peptides

Proteins

Energy Transfer

Quantification

Imaging

Localization

Investigations of the Electronic Structure and Excited State Processes of Tansition Metal Complexes with Polypyridyl and Schiff Base Ligans

Ball, Pamilla J.

January 2005

No description available.

Electronic to Vibrational Energy Transfer from Cl* (3 ²P_1/2) to N₂O(ν₁): Failure of a Simple Kinetic Mechanism

Brumfield, Brian

05 December 2005

No description available.

Chemistry, Physical

failure of a simple kinetic mechanism

Electronic to Vibrational Energy Transfer from Cl^* (²P_1/2) to CH₄ and CD₄

Munson, Brian R.

15 May 2009

No description available.

Chemistry

E-V Energy Transfer

Spin-orbit excited chlorine

Time-resolved IR fluorescence

CARS Measurements of Vibrational Energy Transfer in Nanosecond Pulse Electric Discharges in Nitrogen, Air, and Their Mixtures with Carbon Dioxide

Hung, Yi-chen, Hung

28 December 2016

No description available.

Physical Chemistry

Reducing Threshold of Biexciton Formation in Semiconductor Nanocrystals through Their Self-Assembly into Nano-Antennae

Emara, Mahmoud M.

18 July 2008

No description available.

Chemistry

nanocrystals

semiconductor

quantum dots

energy transfer

optical gain

biexciton

multiexciton

Auger

CdTe

CdSe