Your search keyword '"Ziesche, Ralf"' showing total 4 results

1. Femtosecond multimodal imaging with a laser-driven X-ray source.

Author

Doherty, Adam, Fourmaux, Sylvain, Astolfo, Alberto, Ziesche, Ralf, Wood, Jonathan, Finlay, Oliver, Stolp, Wiebe, Batey, Darren, Manke, Ingo, Légaré, François, Boone, Matthieu, Symes, Dan, Najmudin, Zulfikar, Endrizzi, Marco, Olivo, Alessandro, and Cipiccia, Silvia

Subjects

FEMTOSECOND pulses, ULTRASHORT laser pulses, X-ray imaging, ELECTRON accelerators, LASER-plasma interactions, LINEAR accelerators, BETATRONS

Abstract

Laser-plasma accelerators are compact linear accelerators based on the interaction of high-power lasers with plasma to form accelerating structures up to 1000 times smaller than standard radiofrequency cavities, and they come with an embedded X-ray source, namely betatron source, with unique properties: small source size and femtosecond pulse duration. A still unexplored possibility to exploit the betatron source comes from combining it with imaging methods able to encode multiple information like transmission and phase into a single-shot acquisition approach. In this work, we combine edge illumination-beam tracking (EI-BT) with a betatron X-ray source and present the demonstration of multimodal imaging (transmission, refraction, and scattering) with a compact light source down to the femtosecond timescale. The advantage of EI-BT is that it allows multimodal X-ray imaging technique, granting access to transmission, refraction and scattering signals from standard low-coherence laboratory X-ray sources in a single shot. Laser-plasma electron accelerators are ultracompact and come with an embedded betatron X-ray source with small source size and ultrashort pulse length. The authors combine the edge illumination-beam tracking technique with a compact plasma X-ray source and present a demonstration of multimodal imaging down to the femtosecond timescale. [ABSTRACT FROM AUTHOR]

Published

2023

2. High-speed 4D neutron computed tomography for quantifying water dynamics in polymer electrolyte fuel cells.

Author

Ziesche, Ralf F., Hack, Jennifer, Rasha, Lara, Maier, Maximilian, Tan, Chun, Heenan, Thomas M. M., Markötter, Henning, Kardjilov, Nikolay, Manke, Ingo, Kockelmann, Winfried, Brett, Dan J. L., and Shearing, Paul R.

Subjects

PROTON exchange membrane fuel cells, FUEL cells, NEUTRONS, WATER management, WATER analysis

Abstract

In recent years, low-temperature polymer electrolyte fuel cells have become an increasingly important pillar in a zero-carbon strategy for curbing climate change, with their potential to power multiscale stationary and mobile applications. The performance improvement is a particular focus of research and engineering roadmaps, with water management being one of the major areas of interest for development. Appropriate characterisation tools for mapping the evolution, motion and removal of water are of high importance to tackle shortcomings. This article demonstrates the development of a 4D high-speed neutron imaging technique, which enables a quantitative analysis of the local water evolution. 4D visualisation allows the time-resolved studies of droplet formation in the flow fields and water quantification in various cell parts. Performance parameters for water management are identified that offer a method of cell classification, which will, in turn, support computer modelling and the engineering of next-generation flow field designs. Characterisation of water dynamics in polymer electrolyte fuel cells is important for technology development. Here, the authors demonstrate a 4D neutron imaging technique, enabling quantitative analysis of the local water evolution, and identify performance parameters for water management. [ABSTRACT FROM AUTHOR]

Published

2022

3. 4D imaging of lithium-batteries using correlative neutron and X-ray tomography with a virtual unrolling technique.

Author

Ziesche, Ralf F., Arlt, Tobias, Finegan, Donal P., Heenan, Thomas M. M., Tengattini, Alessandro, Baum, Daniel, Kardjilov, Nikolay, Markötter, Henning, Manke, Ingo, Kockelmann, Winfried, Brett, Dan J. L., and Shearing, Paul R.

Subjects

COMPUTED tomography, TOMOGRAPHY, X-rays, DIFFUSION processes

Abstract

The temporally and spatially resolved tracking of lithium intercalation and electrode degradation processes are crucial for detecting and understanding performance losses during the operation of lithium-batteries. Here, high-throughput X-ray computed tomography has enabled the identification of mechanical degradation processes in a commercial Li/MnO2 primary battery and the indirect tracking of lithium diffusion; furthermore, complementary neutron computed tomography has identified the direct lithium diffusion process and the electrode wetting by the electrolyte. Virtual electrode unrolling techniques provide a deeper view inside the electrode layers and are used to detect minor fluctuations which are difficult to observe using conventional three dimensional rendering tools. Moreover, the 'unrolling' provides a platform for correlating multi-modal image data which is expected to find wider application in battery science and engineering to study diverse effects e.g. electrode degradation or lithium diffusion blocking during battery cycling. The combination of X-ray and neutron CT enables 4D studies, i.e. to explore the evolution of 3D structures with time. Here the authors apply this approach to a Li-ion primary cell, revealing elsewhere unseen trends in the spatial distribution of performance aided by a new 'unrolling' methodology. [ABSTRACT FROM AUTHOR]

Published

2020

4. Author Correction: Femtosecond multimodal imaging with a laser-driven X-ray source.

Author

Doherty, Adam, Fourmaux, Sylvain, Astolfo, Alberto, Ziesche, Ralf, Wood, Jonathan, Finlay, Oliver, Stolp, Wiebe, Batey, Darren, Manke, Ingo, Légaré, François, Boone, Matthieu, Symes, Dan, Najmudin, Zulfikar, Endrizzi, Marco, Olivo, Alessandro, and Cipiccia, Silvia

Subjects

X-ray imaging

Published

2023