Rapid and Quantitative MRI of Chemical Exchange and Magnetization Transfer

Shah, Tejas Jatin

30 July 2010

No description available.

Health Care

CEST

MRI

Pulse Sequence

BIOPARTICLE SEPARATION IN NON-NEWTONIAN FLUID USING PULSED FLOW IN MICRO-CHANNELS

DEVARAKONDA, SURENDRA BALAJI

02 October 2006

No description available.

Blood

bead

separation

non-Newtonian

pulse

RBC

EXPERIMENTAL INVESTIGATION OF SHOCK TRANSFER AND SHOCK INITIATED DETONATION IN A DUAL PULSE DETONATION ENGINE CROSSOVER SYSTEM

Driscoll, Robert B.

21 October 2013

No description available.

Aerospace Materials

Pulse Detonation Engine

Detonation

Crossover

The Use of Sage Simulation Software in the Design and Testing of Sunpower's Pulse Tube Cryocooler

Wilson, Kyle B.

08 December 2005

No description available.

Engineering, Mechanical

Cryocooler

Pulse Tube

Sage

Simulation

Computer controlled generation of PWM waveform using harmonic distortion minimization scheme

Dalvi, Mahesh

January 1997

No description available.

Harmonic

Pulse Width Modulation

AC/DC Converter

Ignition of hydrocarbon fuels by a repetitively pulsed nanosecond pulse duration plasma

Bao, Ainan

07 January 2008

No description available.

Engineering, Mechanical

Nonequilibrium plasma

Nanosecond pulse

Ignition

Stiffness Characteristics of Airfoils Under Pulse Loading

Turner, Kevin E.

January 2009

No description available.

Mechanical Engineering

rub

airfoil

blade

stiffness

pulse

Pulse radiolysis of proteins as a tool to determine the PK[subscript A] of certain histidines on modified and unmodified proteins and the puls radiolysis of disulfides /

Steiner, Jerald Paul,

January 1983

No description available.

Chemistry

Pulse radiolysis

Proteins

Histidine

Sulfides

Study of Ultrashort Pulse Laser Induced Surface Ripples and Investigation of Other Applications of Ultrashort Pulse Laser Micromachining and Ablation

Hsu, Eugene

10 1900

<p> This thesis reports findings from three series of experiments related to ultrashort laser pulse interactions with materials. The first series investigates the formation of laser induced ripples that have spatial periods much shorter than the irradiation wavelength after laser irradiation. The second series of experiments explores the capabilities of ultrashort pulse laser micromachining on optical fiber modifications for niche applications. Lastly, preliminary work in establishing a double-pulse ablation technique is reported. </p> <p> The first set of experiments reported in this thesis investigates the morphology of surface ripples that are generated when irradiated with multiple ultrashort laser pulses. Two types of surface ripples can form after irradiation. The fust type has spatial periods near the wavelength of the irradiation pulses and the second has spatial periods substantially below the irradiation wavelength (typically 114 to 115 of the free-space irradiation wavelength are observed in our studies). These substantially subwavelength ripples form when the irradiation wavelength corresponds to a photon energy that is below the bandgap of the target material. The Ti:Sapphire laser systems used in this series of experiments provides pulses centered around 800 nm. Gallium phosphide (GaP) was chosen to be the main material for investigation since 800 nm corresponds to a photon energy that is below the bandgap of this material; no frequency conversion needs to be carried out when GaP is the material of choice for subwavelength ripples studies. In this series of experiments substantially different irradiation conditions were investigated: pulse durations varied from 150 fs to 7 ns, laser energies ranges from well above the ablation and modification threshold to well below, both 800 nm and 400 nm wavelengths, and "scrambled" (where polarization was rotated between each successive pulse) polarization as well as circular polarization were used. Microscopy techniques employed to study these ripples include optical microscopy, scanning electron microscopy, atomic force microscopy and transmission electron microscopy. Cross-sectional studies with transmission electron microscopy were also carried out by using focused ion beam milling to prepare thin specimens across irradiated regions. Sapphire was also used as the irradiation target for 800 nm and 400 nm pulses since it has a large bandgap and even 400 nm corresponds to an energy that is below its bandgap. Irradiation conditions where the two types of ripples are observed are determined. Also, microscopy of the ripple features provided insights in to the formation mechanism of the subwavelength ripples. </p> <p> In the second series of experiments, preliminary work was performed to investigate the capabilities of ultrashort laser micromachining in fiber optic applications. This series of experiments can be subdivided in to two categories. </p> <p> The goal of the first fiber investigation was to create a slit in a metallic coating deposited on a fiber facet. Such a feature might eliminate the use of external slits (e.g. for spectrometers), especially ifthe output of the fiber depends on its geometry (e.g. polarization-maintaining fiber). The first experiment carried out was micromachining of a ~ 180 nm layer of gold that was deposited on a glass substrate, in order to determine irradiation conditions where the gold layer can be removed while the glass is not damaged. Once the irradiation condition was established by studying the micromachined gold layer on glass substrate, gold layers were deposited on fiber facets for micromachining experiments. The results showed promising potential, but fme tuning of the irradiation parameters, and processing as well as microscopy techniques are needed before useful applications can be realized. </p> <p> The second set of fiber experiments investigates irradiation conditions that are appropriate to micromachine features into fibers such as v-grooves and beveled ends. Preliminary work was carried out to determine a suitable focusing scheme for this application. Different pulse durations and a pulse train were also employed in hope of minimize chipping and cracking. This investigation did not reach a conclusion on whether micromachining with ultrashort laser pulses are in fact suitable for processing of optical fibers, where high quality facets are required. Future investigation could provide further information on the feasibility of laser micromachining on fabricating features in optical fibers. </p> <p> Lastly, a double-pulse ablation scheme was established and explored. Double-pulse ablation had been reported in the literature to improve material removal rate and the appearance of the fmal morphology. However, this setup can be adapted to investigate the ablation mechanisms and provide insight into the state of the material at different time frames of ablation. While the experimental results are preliminary, this technique showed potential, along with possible extensions of this technique, to further investigate the ablation mechanisms. </p> / Thesis / Master of Applied Science (MASc)

Pulse Laser

Ultrashort

Surface Ripples

Laser Micromachining

An Efficient Split-Step Digital Filtering Method in Simulating Pulse Propagation with Polarization Mode Dispersion Effect

He, Kan

January 2007

<p> The rapid increasing bandwidth requirement of communication systems demands powerful numerical simulation tools for optics fiber. The computational efficient, memory saving and stable are of the most important characteristics for any simulation tools used for long-haul and broadband optics fiber. An optimized split-step digital filtering method is developed in this paper. The concept of Fourier integral and Fourier series are used in extracting a FIR filter which is used to fit the original transfer function. A further optimization process which employs windowing technique to improve computation efficiency had also been done. Compared with split-step frequency method, our method improves the computation efficiency. Only simple shifts and multiplications are needed in our method. This optimized digital filtering method differs from the former digital filtering method in a sense that the filter length of the FIR filter we extracted is reduced to a very small number. The computation time can be saved as much as 96% than before. This method can also be used to solve coupled nonlinear Schrodinger equation which governs polarization mode dispersion effect in fibers. A new simulation scheme for PMD is proposed to save computation time. The propagation results shows good accordance to those already published results. </p> / Thesis / Master of Applied Science (MASc)

Split-Step

Digital Filtering

Pulse Propagation

Polarization