Characterization andmodeling of amorphous andcrystalline ratios in poly-acrylates

Jonzon, Julia

January 2020

At Nouryon Stockvik the Expancel production site is located. Expandable microspheres areused in for many types of applications and is a technically challenging product. At ExpancelStockvik they are constantly striving to improve product properties in line with customerexpectations. To be able to do this, it is important to understand the properties of themicrospheres such as crystallinity and crystallite size.Films was prepared from microspheres dissolved in DMA and analyzed with High-resolutionSEM, Powder X-Ray Diffraction and Raman Spectroscopy. The aim was to develop a methodto investigate and determine crystalline ratios and crystallite size within the microsphere filmsand the microspheres before film preparation. The eventual correlation between morphologyand crystallinity was also studied. An attempt of finding an amorphous reference sample wasalso performed, this was done by grinding microspheres in liquid nitrogen, unfortunately, nosuccess was reached. Gauss-fitting was therefore performed to be able to find the amorphousregions of the XRD Diffractogram for the calculations of crystallinity and crystallite size. TheGauss-fitting was successfully performed with good R-square values.During the Raman analysis some fluorescence problems occurred, this problem will probablybe solved if a laser source with higher excitation frequency is used in future analysis. Evenwith fluorescence problems, Raman analysis could successfully be performed and giveinformation of the composition. The crystallite size was in general larger for the microspheresbefore they were prepared from dissolving them to make films. Generally, it seems as there isa correlation between the morphology, crystallinity, and crystallite size.

Crystallinity

Diffractogram

Microspheres

Spectra

Raman spectroscopy

XRD.

Chemical Sciences

Kemi

Studies of Halide Perovskites CsPbX₃, RbPbX₃ (X=Cl^-, Br^-, I^-), and Their Solid Solutions

Linaburg, Matthew Ronald

January 2015

No description available.

Inorganic Chemistry

Chemistry

Materials Science

perovskite

crystallography

cubic

orthorhombic

tetragonal

perovskite

band gap

bond angle

lattice parameters

xrd refinement

XRD

variable temperature XRD

halide

chloride

bromide

rubidium

cesium

lead

diffractogram

powder XRD

solid solution

Quantitative Automated Object Wave Restoration in High-Resolution Electron Microscopy

Meyer, Rüdiger Reinhard

09 December 2002

The main problem addressed by this dissertation is the accurate and automated determination of electron microscope imaging conditions. This enables the restoration of the object wave, which confers direct structural information about the specimen, from sets of differently aberrated images. An important member in the imaging chain is the image recording device, in many cases now a charge-coupled device (CCD) camera. Previous characterisations of these cameras often relied on the unjustified assumption that the Modulation Transfer Function (MTF) also correctly describes the spatial frequency dependent attenuation of the electron shot noise. A new theory is therefore presented that distinguishes between signal and noise transfer. This facilitates the evaluation of both properties using a detailed Monte-Carlo simulation model for the electron and photon scattering in the scintillator of the camera. Furthermore, methods for the accurate experimental determination of the signal and noise transfer functions are presented. In agreement with the Monte-Carlo simulations, experimental results for commercially available CCD cameras show that the signal transfer is significantly poorer than the noise transfer. The centrepiece of this dissertation is the development of new methods for determining the relative aberrations in a set of images and the absolute symmetric aberrations in the restored wave. Both are based on the analysis of the phase information in the Fourier domain and give each Fourier component a weight independent of its strength. This makes the method suitable even for largely crystalline samples with little amorphous contamination, where conventional methods, such as automated diffractogram fitting, usually fail. The method is then extended to also cover the antisymmetric aberrations, using combined beam tilt and focal series. The applicability of the new method is demonstrated with object wave restorations from tilt and focal series of complex inorganic block oxides and of carbon nanotubes filled with one-dimensional inorganic crystals. The latter specimens allowed for the first time a direct comparison between the phase shift in the restored object wave of a specimen with precisely known thickness and the value predicted by simulations.

Aberrationsbestimmung

Elektronenmikroskopie

Linsenfehler

Nanoröhre

Objektwellenrekonstruktion

DigiTEM

Zemlin tableau

aberration correction

aberration determination

carbon nanotube

charge coupled device

detection quantum efficiency

diffractogram

exit wave restoration

filled carbon nanotube

focal series

high resolution electron microscopy

ddc:29

rvk:UH 6300

Abbildungsfehler

Elektronenmikroskopie

Hochauflösendes Verfahren

Linse

Nanoröhre

Quantitative Automated Object Wave Restoration in High-Resolution Electron Microscopy

Meyer, Rüdiger Reinhard

25 November 2002

The main problem addressed by this dissertation is the accurate and automated determination of electron microscope imaging conditions. This enables the restoration of the object wave, which confers direct structural information about the specimen, from sets of differently aberrated images. An important member in the imaging chain is the image recording device, in many cases now a charge-coupled device (CCD) camera. Previous characterisations of these cameras often relied on the unjustified assumption that the Modulation Transfer Function (MTF) also correctly describes the spatial frequency dependent attenuation of the electron shot noise. A new theory is therefore presented that distinguishes between signal and noise transfer. This facilitates the evaluation of both properties using a detailed Monte-Carlo simulation model for the electron and photon scattering in the scintillator of the camera. Furthermore, methods for the accurate experimental determination of the signal and noise transfer functions are presented. In agreement with the Monte-Carlo simulations, experimental results for commercially available CCD cameras show that the signal transfer is significantly poorer than the noise transfer. The centrepiece of this dissertation is the development of new methods for determining the relative aberrations in a set of images and the absolute symmetric aberrations in the restored wave. Both are based on the analysis of the phase information in the Fourier domain and give each Fourier component a weight independent of its strength. This makes the method suitable even for largely crystalline samples with little amorphous contamination, where conventional methods, such as automated diffractogram fitting, usually fail. The method is then extended to also cover the antisymmetric aberrations, using combined beam tilt and focal series. The applicability of the new method is demonstrated with object wave restorations from tilt and focal series of complex inorganic block oxides and of carbon nanotubes filled with one-dimensional inorganic crystals. The latter specimens allowed for the first time a direct comparison between the phase shift in the restored object wave of a specimen with precisely known thickness and the value predicted by simulations.

info:eu-repo/classification/ddc/29

ddc:29