Simulation of the Optical Loop Mirror in Ultrafast Fiber Lasers

Zang, Yimin

29 May 2018

No description available.

Optics

Mode-locked fiber lasers

Nonlinear optical loop mirror

Nonlinear amplifying loop mirror

Saturable absorbing action

Ultrafast pulse propagation

Mono- and Bimetallic Polypyridyl Systems for Solar Energy Applications: Tuning and Identification of Excited States Through Ultrafast Spectroscopy

Whittemore, Tyler

28 September 2018

No description available.

Chemistry

Inorganic Chemistry

Physical Chemistry

spectroscopy

ruthenium

dirhodium

paddlewheels

photochemistry

photophysics

chemistry

ultrafast

inorganic chemistry

dyes

photocatalyst

photocatalysis

catalysis

Coupling Ambient Ionization Mass Spectrometry with Liquid Chromatography and Electrochemistry and Their Applications

Cai, Yi

January 2016

No description available.

Chemistry

Analytical Chemistry

desorption electrospray ionization

probe electrospray ionization

liquid chromatography

electrochemistry

ultrafast separation

Ultrafast Protein Hydration Dynamics and Water-Protein Interactions

Yang, Jin

January 2016

No description available.

Biochemistry

Physics

Biophysics

Ultrafast Spectroscopic Study of Hydration and Conformational Dynamics in Calmodulin

Craigo, Kevin Alan

13 September 2011

No description available.

Biochemistry

Biology

Chemistry

Physical Chemistry

Physics

hydration

calmodulin

conformation

spectroscopic

ultrafast

femtosecond

up-conversion

solvation

tryptophan

protein

Application of Strong Field Physics Techniques to Free Electron Laser Science

Roedig, Christoph Antony

25 June 2012

No description available.

Physics

"free electron laser"

x-ray

ultrafast

"atomic physics"

LCLS

SLAC

XFEL

FEL

Manipulating Photocarrier and Exciton Transport in Hybrid and Molecular Semiconductors

Linrui Jin (13162254)

27 July 2022

<p> Excitons represent the electronic excited state of organic semiconductor and many low-dimensional inorganic semiconductors. In solar energy conversion systems, exciton transport affects how fast the charges reach the electrodes thus governs the performance of photovoltaic cells. In optoelectronic applications such as semiconductor lasers and light-emitting diodes, exciton radiative rate determines the efficiency of luminescence in competition to various nonradiative processes. Therefore, understanding how exciton migrates over space as well as its decay dynamics are vital for the design of highly efficient optoelectronic devices. To interrogate these photophysical processes requires experimental tools with simultaneous high temporal and spatial resolution. In this thesis, I introduce two transient imaging systems (photoluminescence imaging with 300 ps time resolution, and transient absorption microscopy with 200 fs time) that are innovative tools to directly probe excited state dynamics and transport in sub-μm domains. The techniques were applied to a type of promising semiconductor, perovskites, including surface-passivated hybrid perovskite and 2D layered perovskites to explore the fundamental mechanisms that affect exciton transport. The fundamental understanding of excitons shed light on the underlying physics such as exciton delocalization, exciton-exciton interaction, and how these properties affected by the static and dynamic disorders of the material. We further demonstrated a novel twisted superlattice using ultrathin perovskites that confines excitons due to increased density of state from the moiré flat bands. In addition, excitons can be accelerated by strongly interacts photons, forming polariton quasiparticles that possess small effective mass. This is demonstrated by coupling 2D layered perovskites to a plasmonic array. We further showcase the formation of bulk polaritons without an external optical cavity in a self-assembled organic aggregate. Experimental investigation into these intriguing phenomena provide an approach to study fundamental processes such as many-body interaction and quantum coherence. </p>

Photochemistry

Nonlinear optics and spectroscopy

Exciton

Carrier dynamics

Polariton

Ultrafast spectroscopy

Transient Absorption Microscopy

Perovskite

NONLINEAR AND ULTRAFAST OPTICAL STUDIES OF INTERFACIAL PROCESSES IN PHOTOVOLTAIC NANOMATERIALS

FANG, HUI, 0000-0002-4024-1234

January 2020

The development of efficient solar energy conversion devices has attracted much attention. Despite the fact that progress have been achieved, a fundamental understanding examining why efficiency can be improved remains elusive. For example, dye-sensitized solar cells (DSSC) exhibit high conversion efficiency when acetonitrile is used to prepare both the working electrode and the electrolyte. However, the mechanism explaining exactly how solvent influences device performance has not yet been systematically investigated. Another prominent example is the metal/semiconductor heterojunction systems. While it has been demonstrated that such mixed systems can significantly improve solar conversion efficiency, the mechanism of the electron dynamics driving these systems remains controversial. This stems in part from the fact that the experimentally deduced time constants, which are characteristic of such systems, are only ever extracted from phenomenological models and therefore cannot be assigned to specific physical processes. Ultimately, the development of a physical model is necessary to obtain an unambiguous physical picture of the solar conversion process. In this dissertation, the ultrafast nonlinear spectroscopic methods, second harmonic light scattering (SHS) and transient absorption (TA) spectroscopy, have been employed to study dye molecular adsorption and charge transfer dynamics in several solar energy conversion systems, including 1) DSSC, where solvent effects are investigated to understand why acetonitrile is the most effective solvent; 2) Ag/TiO2 heterostructure system, where a physical model is proposed to quantitively analyze the electron dynamics; 3) porphyrin/Ag/TiO2 nanocomposite, where we found there is no electron injection from porphyrin to TiO2 and plasmonic metal can enhance the porphyrin dye adsorption to improve the device efficiency. The propensity for surface adsorption of two related dyes, ortho-ethyl red (o-ER) and para-ethyl red (p-ER), onto TiO2 particles is studied with SHS. While p-ER readily adsorbs onto TiO2, o-ER does not. It is suggested that this difference is linked to the effects of the steric hindrance of the adsorbate. The influence of the solvent on the adsorption of p-ER onto TiO2 is also investigated. Of significance, p-ER can only chemically bond to the TiO2 surface in aprotic solvents, where adsorption free energy scales with solvent polarity. For protic solvents, preferential adsorption of the solvent shell ultimately prevents direct adsorption of p-ER onto the surface of TiO2. Likewise, solvent effects on charge transfer from p-ER to TiO2 are studied by TA. The electron injection rate is shown to be positively related to solvent polarity. Overall, highly polar aprotic solvents are shown to facilitate dye adsorption and electron injection, which helps improve the efficiency of DSSC devices. Ultrafast dynamics of plasmon-induced hot electrons from Ag to TiO2 nanorods are probed by TA. The observed transient signal, which corresponds to the lifetime of the optically generated electrons, is analyzed using a physical model including electron injection, relaxation, band edge annihilation, the surface to bulk diffusion, and back diffusion from the bulk to the surface. A ca. 13 fs electron injection time is deduced for Ag to TiO2, which is faster than that generated in Au and dyes. Additionally, the excited state exciton dynamics of a porphyrin J-aggregate are investigated and subsequently modeled. More rapid dynamics are found following aggregation of the porphyrin, which can be attributed to the inclusion of more efficient relaxation channels. However, no electron injection from the J-aggregate to TiO2 is observed. This likely stems from the negatively charged repulsion between the two components. Further, when the J-aggregate is introduced into an Ag/TiO2 system, optical excitation occurs predominantly in the J-aggregate. This stems either from direct excitation of the J-aggregate or indirect excitation through plasmon-induced resonant energy transfer from Ag. Our results indicate that plasmon can enhance the dye adsorption, which has great potential for designing more efficient plasmonic DSSC devices. / Chemistry

Chemistry

Physical Chemistry

Optics

Electron Dynamics

Molecule Adsorption

Nonlinear Optical Spectroscopy

Photovoltaic and Photocatalysis

Surface and Interface

Ultrafast Spectroscopy

Investigating the Structure Property Relationships in Iridium(III) and Gold Organometallic Complexes

Wilt, Megan

26 August 2022

No description available.

Chemistry

Iridium

gold

photophysics

nonlinear

optical

properties

azadipyrromethene

chromophores

ultrafast

femtosecond

gold(I)

gold(II)

gold(III)

iridium(III)

Time-Resolved Studies of Magnetic and Non-Magnetic Narrow-Gap Semiconductors

Nontapot, Kanokwan

11 September 2008

In recent years, spin relaxation, injection, and manipulation in semiconductors have attracted considerable interest because of several potential applications in "spintronic" devices and the necessity to understand and control spin-based phenomena. In light of the growing interest in spin-related phenomena and devices, there is now renewed interest in the science and engineering of narrow gap semiconductors (NGS). NGS based heterostructures are particularly interesting for spintronic applications due to their large spin-orbit coupling, which leads to considerable zero-field spin splitting. NGS are also candidates for electronic applications, such as high-speed and low-power microprocessors; as reported recently by Intel. Furthermore, as switching rates in electronic devices are pushed to even higher frequencies, it is important to understand dynamics in semiconductors such as NGS on femtosecond time-scales. In this thesis, time-resolved studies of magnetic and non-magnetic NGS using ultrafast-laser spectroscopy techniques such as pump-probe spectroscopy and magneto-optical Kerr/Faraday effect, are reported. Our samples include: InSb-based quantum wells with different confinement potentials; InMnSb films, the newest III-V ferromagnetic semiconductors; and InAs films. The samples for these studies have been provided by the groups of Prof. Santos at the University of Oklahoma, Prof. Furdyna at the University of Notre Dame, and Prof. Guido at Virginia Tech. The objectives in this thesis have been to: a) understand charge/spin dynamics in NGS with novel confinement potentials, b) probe the effect of magnetic impurities on the spin/charge dynamics, and c) develop concepts for spin based device applications. Several specific questions and concepts have been addressed including: the effect of large spin-orbit interaction in NGS on the dynamics, how large Rashba spin splitting in these materials affect the spin coherence life time, and carrier/spin dynamics in ferromagnetic semiconductor structures. / Ph. D.

Narrow gap semiconductors

Ultrafast laser spectroscopy

Spin dynamics

Magneto-optical Kerr/Faraday effect

Time resolved pump/probe