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XUV Transient Absorption Spectroscopy: Probing Laser-Perturbed Dipole Polarization in Single Atom, Macroscopic, and Molecular RegimesLiao, Chen-Ting, Sandhu, Arvinder 08 March 2017 (has links)
We employ an extreme ultraviolet (XUV) pulse to impulsively excite dipole polarization in atoms or molecules, which corresponds to coherently prepared superposition of excited states. A delayed near infrared (NIR) pulse then perturbs the fast evolving polarization, and the resultant absorbance change is monitored in dilute helium, dense helium, and sulfur hexafluoride (SF6) molecules. We observe and quantify the time-dependence of various transient phenomena in helium atoms, including laser-induced phase (LIP), time-varying (AC) Stark shift, quantum path interference, and laser-induced continuum structure. In the case of dense helium targets, we discuss nonlinear macroscopic propagation effects pertaining to LIP and resonant pulse propagation, which account for the appearance of new spectral features in transient lineshapes. We then use tunable NIR photons to demonstrate the wavelength dependence of the transient laser induced effects. In the case of molecular polarization experiment in SF6, we show suppression of XUV photoabsorption corresponding to inter-valence transitions in the presence of a strong NIR field. In each case, the temporal evolution of transient absorption spectra allows us to observe and understand the transient laser induced modifications of the electronic structure of atoms and molecules.
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Exploring Ultrafast Quantum Dynamics of Electrons by Attosecond Transient AbsorptionLiao, Chen-Ting, Liao, Chen-Ting January 2017 (has links)
Quantum mechanical motion of electrons in atoms and molecules is at the heart of many photophysical and photochemical processes. As the natural timescale of electron dynamics is in the range of femtoseconds or shorter, ultrashort pulses are required to study such phenomena. The ultrashort pulse light-matter interaction at high intensity regime can however dramatically alter the atomic and molecular structures. Our current understanding of such transient electronic modification is far from complete, especially when complicated light-induced couplings are involved. In this dissertation, we investigated how a femtosecond strong-field pulse can control or modify the evolution of atomic or molecular polarization, representing electric dipole excitation in various systems. Extreme ultraviolet (XUV) attosecond pulse trains are used to coherently prepare superposition of excited states in various atomic and molecular systems. A subsequent phase-locked infrared (IR) femtosecond pulse is applied to perturb the dipoles, and transient changes in the transmitted XUV spectra are measured. This scheme is termed as XUV attosecond transient absorption spectroscopy. In the first study, we applied this technique to study the modification of Rydberg states in dilute helium gas. We observed several transient changes to the atomic structure, including the ac Stark shift, laser-induced quantum phase, laser-induced continuum structure, and quantum path interference. When the experiments were extended to the study of a dense helium gas sample, new spectral features in the absorption spectra emerged which cannot be explained by linear optical response models. We found that these absorption features arise from the interplay between the XUV resonant pulse propagation and the IR-imposed phase shift. A unified physical model was also developed to account for various scenarios. Extending our work to argon atoms, we studied how an external infrared field can be used to impulsively control different photo-excitation pathways and the transient absorption lineshape of an otherwise isolated autoionizing state. It is found that by controlling the field polarization of the IR pulse, we can modify the transient absorption line shape from Fano-like to Lorentzian-like profiles. Unlike atoms, in our study of autoionizing states of the oxygen molecule, we observed both positive and negative optical density changes for states with different electronic symmetries. The predictions of two distinct and simplified dipole perturbation models were compared against both the experimental results and a full theoretical calculation in order to understand the origin of the sign of absorption change. We relate this symmetry-dependent sign change to the Fano parameters of static photoabsorption. The same approach was applied to study molecular nitrogen, in which we observed the decay dynamics of IR perturbed doubly-excited Rydberg states with many vibrational progressions. In addition, we also conducted experiments to investigate Rydberg state dynamics of other molecular systems such as carbon dioxide. In summary, we experimentally explored the ephemeral light-induced phenomena associated with excited states of atoms and molecules. These studies provide real-time information on ultrafast electronic processes and provide strategies for direct time-domain control of the light-matter interaction.
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Development of a Multiphoton Photoacoustic MicroscopeShelton, Ryan 1983- 14 March 2013 (has links)
Cellular/subcellular imaging of biological tissue is an important tool for understanding disease mechanisms. Many current techniques for subcellular absorption contrast imaging, such as two-photon excited fluorescence (TPEF), require exogenous contrast agents to gain access to many naturally occurring biomolecules. Non-fluorescent biomolecules must have a fluorescent marker (tag) chemically bound in order to be observed by TPEF. Contrast agents and markers, while effective, are not an optimal solution because they can change the local environment in the biological system and require FDA approval for human use. Photoacoustic microscopy (PAM) is an imaging modality with high endogenous absorption contrast and penetration depth due to its ability to detect acoustic waves, which are attenuated much less than light in tissue. However, this technique suffers from poor axial resolution, precluding it from consideration for subcellular imaging.
This manuscript describes the author's efforts to improve the axial resolution of traditional PAM by merging it with pump-probe spectroscopy. Pump-probe spectroscopy is a non-linear optical technique that exploits a physical process called transient absorption, providing spatial resolution equivalent to two-photon microscopy and access to molecular-specific traits, such as the ground state recovery time and transient absorption spectrum. These traits provide molecular contrast to the imaging technique, which is highly desirable in a complex, multi-chromophore biological system.
In this manuscript, a novel technique called transient absorption ultrasonic microscopy (TAUM) is designed and characterized in detail. A second-generation TAUM system is also described, which improves speed and sensitivity of TAUM by up to 1000-fold. This system is validated by collecting volumes of red blood cells in blood smears and tissue samples. These results constitute the first time single cells have been fully resolved using a photoacoustic microscope. Finally, the TAUM system is modified to measure chromophore ground state recovery times. This technique is validated by measuring the recovery time of Rhodamine 6G, which matches well with published values of the fluorescence lifetime. Recovery times of oxidized and reduced forms of hemoglobin are also measured and shown to statistically differ from one another, suggesting the possibility of subcellular measurements of oxygen saturation in future iterations of TAUM.
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Investigation of Coherent Vibrational Signatures with Impulsive Transient Absorption SpectroscopyFitzpatrick, Colin, 0000-0003-3422-2894 January 2021 (has links)
In Chapter 1, we present the background for transient absorption spectroscopy through the polarization response of a material to an electric field which gives rise to linear and non-linear processes. We then discuss a theoretical description of how vibrational coherences are formed via four-wave mixing and impulsive excitation. We also describe signatures of coherent wavepackets in transient absorption and the application of vibrational coherences, specifically to observe non-radiative processes. We then summarize two previous studies using impulsive transient absorption on cresyl violet, the differences in the coherent dynamics reported, and the motivations behind the experiments presented in this work. Chapter 2 pertains to the apparatus used to perform the transient absorption experiments. We detail the source for the generation of ultrashort laser pulses (durations of less than 10 fs) used for the pump and probe from an argon-based white-light filament and non-colinear optical parametric amplifier. Two-dimensional shearing interferometry, the method used to measure the ultrashort pulses across a large portion of the visible spectrum (500-750 nm), is discussed. The retrieved temporal, spectral, and phase profiles of the pump and probe pulses are presented. Finally, the sample preparation for cresyl violet is described as well as the detection method and data processing used to generate the figures throughout this work.
In Chapter 3, we present the results of impulsive transient absorption spectroscopy of cresyl violet perchlorate under four pump conditions. First, we report a study on controlling the formation of vibrational coherences on the ground or excited electronic states of cresyl violet by tuning the pump conditions from an off-resonant to a resonant scheme. The decay of the electronic population and positions of the stimulated emission and excited-state absorption maximums shows a dependence on the pump wavelength. Higher excitation frequencies blueshifts the stimulated emission 18 meV and red shifts excited-state absorption by 4 meV at early times compared to only 13 meV and 2 meV when using lower excitation frequencies. Coherent vibrations are observed and persist for approximately 6 ps after excitation, with phase flips appearing at 593 nm, the absorption maximum, after off-resonant excitation and at the emission (619 nm) and excited-state absorption (500 nm) maximums after resonant excitation. The ground- and excited-state vibrational modes are characterized by Fourier transform Raman spectroscopy. The excited-state vibration spectrum is shown to share nearly identical features as the ground-state, with each vibration slightly red-shifted, 2-10 cm-1, from the corresponding mode in the ground-state, particularly a prominent peak appearing at 594 cm-1 in the ground-state and 589 cm-1 in the excited-state. Next, two additional pump conditions using broadband and partially resonant pump pulses are explored to replicate the conflicting reports of non-adiabatic crossings in cresyl violet. Constant phase-flips observed in the control studies are replaced with phase flips that appear and disappear over several picoseconds. The Fourier Raman spectrum of the coherent signal after broadband excitation displays a mix of ground- and excited-state features, particularly prominent peaks at both 589 cm-1 and 594 cm-1.
In Chapter 4, we analyze the coherent signals after broadband excitation using a Fourier filtering technique to isolate the ground- or excited-state coherent dynamics by carefully selecting representative vibrational modes for each state. Using a narrow filter to isolate the 589 cm-1 and 595 cm-1 features in the broadband Fourier Raman spectrum successfully isolates coherent vibrations with phase flips at either the emission and excited-state absorption maximums or the ground-state absorption maximum, respectively. A filter that includes both features generates apparent phase-flips that only appear for ~1ps and at probe wavelengths that do not correspond to the emission or absorption maximums.
In Chapter 5, we present a simulation of the coherent signals using a model of two wavepackets with carrier frequencies of 589 cm-1 and 595 cm-1 and dephasing rates of 2 and 3 ps, respectively. Comparison to the broadband pump conditions and Fourier filtered coherent oscillations shows that the complex temporal dynamics observed are adequately described by the linear interference of two vibrational coherences evolving on different electronic potential energy surfaces, without the need to invoke non-adiabatic dynamics. / Chemistry
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ULTRAFAST PHOTOEXCITATION STUDIES OF CONCENTRATED SOLUTIONS OF ALKALI METAL HALIDESRodrigo, Udaya Indike 03 August 2006 (has links)
No description available.
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Structural, Spectroscopic, and Kinetic Investigation of Modified Photochromic Ruthenium Sulfoxide ComplexesMalizia, Jason Patrick 02 May 2014 (has links)
No description available.
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An investigation of the excited state properties of (E)-1,2-bis(2,2'-bithiophene-5-yl)ethylene using femtosecond time resolved spectroscopyCook, Samuel C. January 2016 (has links)
No description available.
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Pyridinium Salts As Electron Traps: An Ultrafast Transient Absorption Spectroscopy StudyKhubaibullin, Ilnur 22 November 2016 (has links)
No description available.
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Ultrafast spectroscopy and dynamics of nitrenes and carbenesPolshakov, Dmitrii A. 08 November 2005 (has links)
No description available.
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Excuted state dynamics in DNA base monomers: the effects of solvent and chemical modification in ultrafast internal conversionHare, Patrick Michael 05 January 2007 (has links)
No description available.
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