Nickel-rich layered cathode materials promise high energy density for next-generation
batteries when coupled with lithium metal anodes. However, the practical capacities …

Imaging across different scales is essential for understanding healthy organ morphology
and pathophysiological changes. The macro-and microscale three-dimensional morphology …

Improving composite battery electrodes requires a delicate control of active materials and
electrode formulation. The electrochemically active particles fulfill their role as energy …

Imaging intact human organs from the organ to the cellular scale in three dimensions is a
goal of biomedical imaging. To meet this challenge, we developed hierarchical phase …

The microstructure of a composite electrode determines how individual battery particles are
charged and discharged in a lithium-ion battery. It is a frontier challenge to experimentally …

Analysis of tomographic datasets at synchrotron light sources (including X-ray transmission
tomography, X-ray fluorescence microscopy and X-ray diffraction tomography) is becoming …

Object reconstruction from a series of projection images, such as in computed tomography
(CT), is a popular tool in many different application fields. Existing commercial software …

We assess the heterogeneous electrochemistry and mechanics in a composite electrode of
commercial batteries using synchrotron X-ray tomography analysis and microstructure …

The multiscale chemomechanical interplay in lithium‐ion batteries builds up mechanical
stress, provokes morphological breakdown, and leads to state of charge heterogeneity …

Automated blood vessel segmentation is critical for biomedical image analysis, as vessel
morphology changes are associated with numerous pathologies. Still, precise segmentation …