Your search keyword '"Westermeier, F."' showing total 8 results

1. Correcting angular distortions in Bragg coherent X-ray diffraction imaging.

Author

Chen H, Dzhigaev D, Björling A, Westermeier F, Lyubomirskiy M, Stuckelberger M, and Wallentin J

Abstract

Bragg coherent X-ray diffraction imaging (BCDI) has emerged as a powerful technique for strain imaging and morphology reconstruction of nanometre-scale crystals. However, BCDI often suffers from angular distortions that appear during data acquisition, caused by radiation pressure, heating or imperfect scanning stages. This limits the applicability of BCDI, in particular for small crystals and high-flux X-ray beams. Here, we present a pre-processing algorithm that recovers the 3D datasets from the BCDI dataset measured under the impact of large angular distortions. We systematically investigate the performance of this method for different levels of distortion and find that the algorithm recovers the correct angles for distortions up to 16.4× (1640%) the angular step size dθ = 0.004°. We also show that the angles in a continuous scan can be recovered with high accuracy. As expected, the correction provides marked improvements in the subsequent phase retrieval., (open access.)

Published

2024

2. High-pressure X-ray photon correlation spectroscopy at fourth-generation synchrotron sources.

Author

Cornet A, Ronca A, Shen J, Zontone F, Chushkin Y, Cammarata M, Garbarino G, Sprung M, Westermeier F, Deschamps T, and Ruta B

Abstract

A new experimental setup combining X-ray photon correlation spectroscopy (XPCS) in the hard X-ray regime and a high-pressure sample environment has been developed to monitor the pressure dependence of the internal motion of complex systems down to the atomic scale in the multi-gigapascal range, from room temperature to 600 K. The high flux of coherent high-energy X-rays at fourth-generation synchrotron sources solves the problems caused by the absorption of diamond anvil cells used to generate high pressure, enabling the measurement of the intermediate scattering function over six orders of magnitude in time, from 10 -3  s to 10 3  s. The constraints posed by the high-pressure generation such as the preservation of X-ray coherence, as well as the sample, pressure and temperature stability, are discussed, and the feasibility of high-pressure XPCS is demonstrated through results obtained on metallic glasses., (open access.)

Published

2024

3. A new experimental setup for combined fast differential scanning calorimetry and X-ray photon correlation spectroscopy.

Author

Martinelli A, Baglioni J, Sun P, Dallari F, Pineda E, Duan Y, Spitzbart-Silberer T, Westermeier F, Sprung M, and Monaco G

Abstract

Synchrotron-radiation-based techniques are a powerful tool for the investigation of materials. In particular, the availability of highly brilliant sources has opened the possibility to develop techniques sensitive to dynamics at the atomic scale such as X-ray photon correlation spectroscopy (XPCS). XPCS is particularly relevant in the study of glasses, which have been often investigated at the macroscopic scale by, for example, differential scanning calorimetry. Here, we show how to adapt a Flash calorimeter to combine XPCS and calorimetric scans. This setup paves the way to novel experiments requiring dynamical and thermodynamic information, ranging from the study of the crystallization kinetics to the study of the glass transition in systems that can be vitrified thanks to the high cooling rates reachable with an ultrafast calorimeter., (open access.)

Published

2024

4. Automated matching of two-time X-ray photon correlation maps from phase-separating proteins with Cahn-Hilliard-type simulations using auto-encoder networks.

Author

Timmermann S, Starostin V, Girelli A, Ragulskaya A, Rahmann H, Reiser M, Begam N, Randolph L, Sprung M, Westermeier F, Zhang F, Schreiber F, and Gutt C

Abstract

Machine learning methods are used for an automated classification of experimental two-time X-ray photon correlation maps from an arrested liquid-liquid phase separation of a protein solution. The correlation maps are matched with correlation maps generated with Cahn-Hilliard-type simulations of liquid-liquid phase separations according to two simulation parameters and in the last step interpreted in the framework of the simulation. The matching routine employs an auto-encoder network and a differential evolution based algorithm. The method presented here is a first step towards handling large amounts of dynamic data measured at high-brilliance synchrotron and X-ray free-electron laser sources, facilitating fast comparison with phase field models of phase separation., (© Sonja Timmermann et al. 2022.)

Published

2022

5. Implications of disturbed photon-counting statistics of Eiger detectors for X-ray speckle visibility experiments.

Author

Möller J, Reiser M, Hallmann J, Boesenberg U, Zozulya A, Rahmann H, Becker AL, Westermeier F, Zinn T, Zontone F, Gutt C, and Madsen A

Abstract

This paper reports on coherent scattering experiments in the low-count regime with less than one photon per pixel per acquisition on average, conducted with two detectors based on the Eiger single-photon-counting chip. The obtained photon-count distributions show systematic deviations from the expected Poisson-gamma distribution, which result in a strong overestimation of the measured speckle contrast. It is shown that these deviations originate from an artificial increase of double-photon events, which is proportional to the detected intensity and inversely proportional to the exposure time. The observed miscounting effect may have important implications for new coherent scattering experiments emerging with the advent of high-brilliance X-ray sources. Different correction schemes are discussed in order to obtain the correct photon distributions from the data. A successful correction is demonstrated with the measurement of Brownian motion from colloidal particles using X-ray speckle visibility spectroscopy.

Published

2019

6. Brownian and advective dynamics in microflow studied by coherent X-ray scattering experiments.

Author

Urbani R, Westermeier F, Banusch B, Sprung M, and Pfohl T

Abstract

Combining microfluidics with coherent X-ray illumination offers the possibility to not only measure the structure but also the dynamics of flowing samples in a single-scattering experiment. Here, the power of this combination is demonstrated by studying the advective and Brownian dynamics of colloidal suspensions in microflow of different geometries. Using an experimental setup with a fast two-dimensional detector and performing X-ray correlation spectroscopy by calculating two-dimensional maps of the intensity auto-correlation functions, it was possible to evaluate the sample structure and furthermore to characterize the detailed flow behavior, including flow geometry, main flow directions, advective flow velocities and diffusive dynamics. By scanning a microfocused X-ray beam over a microfluidic device, the anisotropic auto-correlation functions of driven colloidal suspensions in straight, curved and constricted microchannels were mapped with the spatial resolution of the X-ray beam. This method has not only a huge potential for studying flow patterns in complex fluids but also to generally characterize anisotropic dynamics in materials.

Published

2016

7. In situ X-ray crystallographic study of the structural evolution of colloidal crystals upon heating.

Author

Zozulya AV, Meijer JM, Shabalin A, Ricci A, Westermeier F, Kurta RP, Lorenz U, Singer A, Yefanov O, Petukhov AV, Sprung M, and Vartanyants IA

Abstract

The structural evolution of colloidal crystals made of polystyrene hard spheres has been studied in situ upon incremental heating of a crystal in a temperature range below and above the glass transition temperature of polystyrene. Thin films of colloidal crystals having different particle sizes were studied in transmission geometry using a high-resolution small-angle X-ray scattering setup at the P10 Coherence Beamline of the PETRA III synchrotron facility. The transformation of colloidal crystals to a melted state has been observed in a narrow temperature interval of less than 10 K.

Published

2013

8. Fast two-dimensional detection for X-ray photon correlation spectroscopy using the PILATUS detector.

Author

Westermeier F, Autenrieth T, Gutt C, Leupold O, Duri A, Menzel A, Johnson I, Broennimann C, and Grübel G

Abstract

The first X-ray photon correlation spectroscopy experiments using the fast single-photon-counting detector PILATUS (Paul Scherrer Institut, Switzerland) have been performed. The short readout time of this detector permits access to intensity autocorrelation functions describing dynamics in the millisecond range that are difficult to access with charge-coupled device detectors with typical readout times of several seconds. Showing no readout noise the PILATUS detector enables measurements of samples that either display fast dynamics or possess only low scattering power with an unprecedented signal-to-noise ratio.

Published

2009