This thesis provides the first successful study of jump diffusion processes in glasses on the atomic scale, utilizing a novel coherent technique. This new method, called atomic-scale X-ray Photon Correlation Spectroscopy or aXPCS, has only recently been proven to be able to capture diffusion processes with atomic resolution in crystal systems.
With this new toolkit for studying atomic diffusion in amorphous systems, new insight into basic processes in a wide range of technically relevant materials, like fast ionic conductors, can be obtained.
Introduction.- Theory.- Experimental.- Data Analysis.- Proof of Concept: Direct Observation of Atomic Diffusion in Glasses.- Practical Application: Tailoring Fast Ionic Diffusion.- Conclusion.
This thesis provides the first successful study of jump diffusion processes in glasses on the atomic scale, utilizing a novel coherent technique. This new method, called atomic-scale X-ray Photon Correlation Spectroscopy or aXPCS, has only recently been proven to be able to capture diffusion processes with atomic resolution in crystal systems.
With this new toolkit for studying atomic diffusion in amorphous systems, new insight into basic processes in a wide range of technically relevant materials, like fast ionic conductors, can be obtained.
Nominated as an outstanding Ph.D. thesis by the University of Vienna, Austria
Advances the technical forefront of X-ray scattering methods by showing how atomic diffusion can be measured in glasses
Demonstrates with detailed figures the crucial aspects of building a stable sample environment for atomic-resolution measurements
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