Laser Induced Breakdown Spectroscopy: Investigation Of Line Profiles, Slurries And Artifical [Sic] Neural Network Prediction

Oh, Seong Yong

15 December 2007

Laser induced breakdown spectroscopy (LIBS) was tested to examine its applicability to remote and in suit analysis in inaccessible situation. Two types of liquid sample (slurry) prepared for simulating vitrification of liquid hazardous wastes was tested. In situ analysis ability makes the LIBS technique practical for analysis of the slurry samples during vitrification, which is in inaccessible situation. For the first slurry sample, two slurry circulation systems were devised to overcome major technical problems associated with LIBS measurements of slurry samples - namely sedimentation and change in the lens-to-sample distance (L.T.S.D) during measurement. The second slurry sample contained less water and is able to be managed in a small glass container during test. We applied direct analysis of slurry sample filled in glass container. Spectroscopic analysis was performed using two different detection systems: Czerny-Turner and Echelle spectrometer systems. In particular, spectroscopic analysis of data from an echelle spectrometer shows the high efficiency for simultaneously determining physical quantities of all elements of interest. We also evaluate LIBS technique to tin alloy samples for the purpose of quantitative analysis by using Echelle spectrometer system. Unknown samples without information of elemental composition were tested to estimate several sample compositions simultaneously. An artificial neural network, calibration method, and chemical analysis were applied to estimate the elemental concentrations of impurities in tin (Sn) alloy.

Slurry

Laser induced breakdown spectroscopy

Line profile

Deformation Study of Nanocrystalline Ni-Fe Alloy using Synchrotron Diffraction

Li, Li

01 August 2010

This dissertation addresses two critical issues in the deformation of nc metals and alloys: (1) A stress-induced genuine grain growth after the plastic deformation rather than just a change of the grain shape; (2) A systematically quantitative study of micrsostructural evolution during the plastic deformation. These two critical issues point to the deformation of nc materials with the average-grain sizes within the range of 10 to 50 nm, which is the most interesting and controversial region in the current time. The current study provides a systematic and detailed microstructural evolution for this region, which is definitely beneficial for the investigation of the deformation mechanism in this region, especially for the simulation. The main experimental and data-analysis methods employed in this research are synchrotron high-energy X-ray diffraction, X-ray line profile analysis, and texture analysis. The combination of these methods is beneficial to the accurate microstructural interpretation of the bulk materials.

Synchrotron

Alloy

Deformation

Microstructure

Line Profile Analysis

Texture

Metallurgy

An investigation into the formation and stability of dislocation loops in irradiated Zr alloys

Topping, Matthew

January 2017

The present PhD project was carried out as part of an EPSRC Leadership Fellowship for the study of irradiation damage in zirconium alloys. The National Nuclear Laboratory (NNL) directly supported the project in terms of additional funding and insightful discussions regarding irradiation damage in zirconium alloys. The research carried out within the project aims to gain a better understanding of both a- and c-loops, formed during irradiation damage in zirconium alloys. A range of techniques have been utilised to assess the morphology and density of the dislocation loops after proton-irradiations. These techniques include transmission electron microscopy (TEM), energy dispersive X-ray spectroscopy (EDS) and line profile analysis (LPA) using synchrotron X-ray diffraction (SXRD) profiles and analysing the data utilizing the extended convolutional multiple whole profile (CMWP) analysis software. The effect of experimental conditions on dislocation loop formation and stability of a-loops during post-irradiation annealing have also been investigated. Proton-irradiations were carried out on the commercial alloys Zircaloy-2, Optimized ZIRLOTM and also on binary Zr-0.1Fe and Zr-0.6Fe alloys. A mechanism has been proposed as to the effect of Fe redistribution on dislocation loop formation. By comparing proton-irradiated Zr-0.1Fe and Zircaloy-2 alloys it was possible to investigate the effect of increased amount of Fe redistribution, which occurs from secondary phase particle (SSP) dissolution, on the microstructural features that develop during irradiation. Zircaloy-2 has a higher density of SPPs and these are more homogenously distributed throughout the matrix in comparison to the Zr3Fe SPPs found in the Zr-0.1Fe alloy. It was found that Fe redistribution facilitates the formation of Fe-rich nano-precipitation. Bright-field STEM imaging has been used to image a- and c-loops and it was found that Zircaloy-2 had a lower dislocation line density compared to Zr-0.1Fe for both types of loops at similar damage levels. Therefore it has been proposed that Fe redistributed from SPPs precipitates in the matrix and the subsequent irradiation-induced precipitates act as annihilation sites for point defects; therefore preventing the formation of new dislocation loops and the growth of existing loops. In order to assess the effect of proton-irradiation temperature on a-loops, Zircaloy-2 and Optimized ZIRLOTM were proton irradiated to 2.3 dpa at 280°C, 350°C and 450°C. It was found that the a-loop density dropped in both alloys as irradiation temperature was increased and the a-loop diameter decreased. The changes in the density and size were more dramatic in Zircaloy-2 and this was explained by the presence of fine irradiation induced clustering of Nb seen in Optimized ZIRLOTM. These trends were calculated from both STEM imaging and CMWP, highlighting the suitability of using CMWP to investigate irradiation-induced dislocations. Finally the stability of the a-loops in proton-irradiated Zr-Fe binary alloys were investigated using novel in-situ SXRD and TEM annealing experiments. From CMWP analysis of the profiles generated during the in-situ annealing of a Zr-0.6Fe 3 dpa sample it was shown that the majority of the annealing takes place between 300°C-400°C. This was highlighted by a period of no change in the dislocation density up to 300°C, after which the density drops dramatically. In-situ annealing of a 1.5 dpa Zr-0.1Fe sample in the TEM allowed for the observation of a-loop gliding along prismatic planes enabling the annealing process taking place between 280°C-450°C, i.e. a similar temperature range at which SXRD analysis indicates the greatest level of annealing.

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A Study of the H-alpha Emission Line Shape in Beta Lyrae

Magno, Macon, Ignace, Richard

05 April 2018

Beta Lyrae is a complex binary star system with a 13-day orbital period containing two massive stars that are in the process of mass reversal accretion. The primary star is the higher mass star which is gaining mass from the secondary star. This reversal mass accretion causes gas to build and form a disk around the primary star. The disk is geometrically and optically thick. Previous interferometric studies in Optical and Infrared wavelengths have shown that a bipolar jet exists in the system and suggest that the jet contributes to the H-alpha emission. Meanwhile, other studies have suggested that the disk contributes to the H-alpha emission. We have taken into account various factors to model the emission of H-alpha from Beta Lyrae. The observed profile is double-peaked and varies with orbital phase. We found that the jet produces a single-peak for H-alpha emission. Meanwhile, the disk produces a double-peak for H-alpha emission if it is based on Keplerian motion. We use our model to interpret the observed H-alpha emission variations in the line shape with orbital phase.

binary stars

eclipsing

Beta Lyrae

line profile

H-alpha

Modeling X-ray Emission Line Profiles from Massive Star Winds - A Review

Igance, Richard

01 September 2016

The Chandra and XMM-Newton X-ray telescopes have led to numerous advances in the study and understanding of astrophysical X-ray sources. Particularly important has been the much increased spectral resolution of modern X-ray instrumentation. Wind-broadened emission lines have been spectroscopically resolved for many massive stars. This contribution reviews approaches to the modeling of X-ray emission line profile shapes from single stars, including smooth winds, winds with clumping, optically thin versus thick lines, and the effect of a radius-dependent photoabsorption coefficient.

x-rays

massive stars

stellar winds

line profile modeling

stellar mass loss

Physics and Astronomy

Astrophysics and Astronomy

A Study of Hα Line Profile Variations in β Lyr

Ignace, Richard, Gray, Sharon K., Magno, Macno A., Henson, Gary D., Massa, Derek

17 August 2018

We examine over 160 archival Hα spectra from the Ritter Observatory for the interacting binary β Lyr obtained between 1996 and 2000. The emission is characteristically double-peaked, but asymmetric, and with an absorption feature that is persistently blueshifted. Using a set of simplifying assumptions, phase varying emission line profiles are calculated for Hα formed entirely in a Keplerian disk, and separately for the line formed entirely from an off-center bipolar flow. However, a dynamic spectrum of the data indicates that the blueshifted feature is not always present, and the data are even suggestive of a drift of the feature in velocity shift. We explore whether a circumbinary envelope, hot spot on the accretion disk, or accretion stream could explain the observations. While none are satisfactory, an accretion stream explanation is somewhat promising.

line profile variations

accretion

accretion disks

eclisping

binaries

visual

stars

Physics and Astronomy

Astrophysics and Astronomy

Time-series Analysis of Line Profile Variability in Optical Spectra of ε Orionis

Thompson, Gregory Brandon

23 September 2009

No description available.

Astronomy

Astrophysics

line profile variability

time-series analysis

massive stars

early-type stars

hot supergiants

stellar winds

stellar pulsations

Simulation and modeling of the powder diffraction pattern from nanoparticles: studying the influence of surface strain

Beyerlein, Kenneth Roy

07 July 2011

Accurate statistical characterization of nanomaterials is crucial for their use in emerging technologies. This work investigates how different structural characteristics of metal nanoparticles influence the line profiles of the corresponding powder diffraction pattern. The effects of crystallite size, shape, lattice dynamics, and surface strain are all systematically studied in terms of their impact on the line profiles. The studied patterns are simulated from atomistic models of nanoparticles via the Debye function. This approach allows for the existing theories of diffraction to be tested, and extended, in an effort to improve the characterization of small crystallites. It also begins to allow for the incorporation of atomistic simulations into the field of diffraction. Molecular dynamics simulations are shown to be effective in generating realistic structural models and dynamics of an atomic system, and are then used to study the observed features in the powder diffraction pattern. Furthermore, the characterization of a sample of shape controlled Pt nanoparticles is carried out through the use of a developed Debye function analysis routine in an effort to determine the predominant particle shape. The results of this modeling are shown to be in good agreement with complementary characterization methods, like transmission electron microscopy and cyclic voltammetry.

Nanoparticles

Molecular dynamics

Line profile analysis

X-ray diffraction

Materials characterization

Nanoparticles

X-rays Diffraction

Strain theory (Chemistry)

Surfaces

Powders Optical properties

Aplicações do método Warren-Averbach de análise de perfis de difração / Applications of the Warren-Averbach method of X-ray diffraction line profile analysis

Rodrigo Uchida Ichikawa

22 November 2013

O objetivo deste trabalho foi desenvolver e implementar uma metodologia envolvendo a análise de perfis de difração de raios X (X-ray Line Profile Analysis - XLPA) para o estudo e determinação do tamanho médio de cristalitos e microdeformação em materiais. Para isto houve o desenvolvimento de um programa computacional para facilitar o tratamento dos picos presentes em um difratograma e realizar a deconvolução de perfis através do Método de Stokes para se corrigir a contribuição instrumental nos perfis de difração. Os métodos de XLPA de espaço real estudados e aplicados neste trabalho foram os métodos de Scherrer, Williamson-Hall e Single-Line (ou Linha Única) e o método de Warren-Averbach de espaço de Fourier. Além disso, utilizando-se um modelamento matemático foi possível calcular a distribuição de tamanhos de cristalitos para um caso isotrópico, onde considerou-se a distribuição log-normal e cristalitos com forma esférica. Foi possível demonstrar que a teoria proposta pode ser considerada como uma boa aproximação avaliando-se uma razão de dispersão. As metodologias descritas acima foram aplicadas em dois materiais distintos: na liga metálica Zircaloy-4 e em ZnO. / The objective of this work was to develop and implement a methodology of X-ray Line Profile Analysis (XLPA) for the study and determination of the mean crystallite sizes and microstrains in materials. A computer program was developed to speed up the treatment of diffraction peaks and perform the deconvolution utilizing the Stokes method to correct the instrumental contribution in the X-ray diffraction measurements. The XLPA methods used were the Scherrer, Williamson-Hall and Single-Line methods, which can be called real space methods, and the Fourier space method of Warren-Averbach. Furthermore, considering a mathematical modelling it was possible to calculate the crystallite size distribution, considering the log-normal distribution and spherical crystallites. It was possible to demonstrate the proposed theory can provide reliable results evaluating a dispersion parameter. The methodologies described above were applied in two distinct materials: in the alloy Zircaloy-4 and in ZnO.

análise de Fourier

Método de Warren-Averbach

microdeformação

tamanho médio de cristalitos

mean crystallite size

microstrain

Warren-Averbach method

X-ray line profile analysis

Aplicações do método Warren-Averbach de análise de perfis de difração / Applications of the Warren-Averbach method of X-ray diffraction line profile analysis

Ichikawa, Rodrigo Uchida

22 November 2013

O objetivo deste trabalho foi desenvolver e implementar uma metodologia envolvendo a análise de perfis de difração de raios X (X-ray Line Profile Analysis - XLPA) para o estudo e determinação do tamanho médio de cristalitos e microdeformação em materiais. Para isto houve o desenvolvimento de um programa computacional para facilitar o tratamento dos picos presentes em um difratograma e realizar a deconvolução de perfis através do Método de Stokes para se corrigir a contribuição instrumental nos perfis de difração. Os métodos de XLPA de espaço real estudados e aplicados neste trabalho foram os métodos de Scherrer, Williamson-Hall e Single-Line (ou Linha Única) e o método de Warren-Averbach de espaço de Fourier. Além disso, utilizando-se um modelamento matemático foi possível calcular a distribuição de tamanhos de cristalitos para um caso isotrópico, onde considerou-se a distribuição log-normal e cristalitos com forma esférica. Foi possível demonstrar que a teoria proposta pode ser considerada como uma boa aproximação avaliando-se uma razão de dispersão. As metodologias descritas acima foram aplicadas em dois materiais distintos: na liga metálica Zircaloy-4 e em ZnO. / The objective of this work was to develop and implement a methodology of X-ray Line Profile Analysis (XLPA) for the study and determination of the mean crystallite sizes and microstrains in materials. A computer program was developed to speed up the treatment of diffraction peaks and perform the deconvolution utilizing the Stokes method to correct the instrumental contribution in the X-ray diffraction measurements. The XLPA methods used were the Scherrer, Williamson-Hall and Single-Line methods, which can be called real space methods, and the Fourier space method of Warren-Averbach. Furthermore, considering a mathematical modelling it was possible to calculate the crystallite size distribution, considering the log-normal distribution and spherical crystallites. It was possible to demonstrate the proposed theory can provide reliable results evaluating a dispersion parameter. The methodologies described above were applied in two distinct materials: in the alloy Zircaloy-4 and in ZnO.

análise de Fourier

mean crystallite size

Método de Warren-Averbach

microdeformação

microstrain

tamanho médio de cristalitos

Warren-Averbach method

X-ray line profile analysis