The rapidly growing use of imaging infrastructure in the energy materials domain drives significant data accumulation in terms of their amount and complexity. The applications of routine techniques for image processing in materials research are often ad hoc, indiscriminate, and empirical, which renders the crucial task of obtaining reliable metrics for quantifications obscure. Moreover, these techniques are expensive, slow, and often involve several preprocessing steps. This paper presents a novel deep learning-based approach for the high-throughput analysis of the particle size distributions from transmission electron microscopy (TEM) images of carbon-supported catalysts for polymer electrolyte fuel cells. A dataset of 40 high-resolution T...
We describe nNPipe for the automated analysis of morphologically diverse catalyst materials. Automat...
Metallic nanoparticles were analysed with respect to size and shape by a machine learning approach. ...
Phase-contrast transmission electron microscopy (TEM) is a powerful tool for imaging the local atomi...
The rapidly growing use of imaging infrastructure in the energy materials domain drives significant ...
Recognition and measuring particles on microscopy images is an important part of many scientific stu...
The performance of polymer electrolyte fuel cells decisively depends on the structure and processes ...
Single-atom catalytic sites may have existed in all supported transition metal catalysts since their...
This project aims to advance the rate of material science study by automating one highly time consum...
Single-atom catalytic sites may have existed in all supported transition metal catalysts since their...
An essential application of electron microscopy is to provide feedback to tune the fabrication of na...
International audienceIn situ transmission electron microscopy (TEM) studies of dynamic events produ...
Nanoparticles occur in various environments as a consequence of man-made processes, which raises con...
The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission el...
Scanning transmission electron microscopy (STEM) is an indispensable tool for atomic-resolution stru...
In order to understand how changes to a material at the atomic and nano-scales impact the way a mate...
We describe nNPipe for the automated analysis of morphologically diverse catalyst materials. Automat...
Metallic nanoparticles were analysed with respect to size and shape by a machine learning approach. ...
Phase-contrast transmission electron microscopy (TEM) is a powerful tool for imaging the local atomi...
The rapidly growing use of imaging infrastructure in the energy materials domain drives significant ...
Recognition and measuring particles on microscopy images is an important part of many scientific stu...
The performance of polymer electrolyte fuel cells decisively depends on the structure and processes ...
Single-atom catalytic sites may have existed in all supported transition metal catalysts since their...
This project aims to advance the rate of material science study by automating one highly time consum...
Single-atom catalytic sites may have existed in all supported transition metal catalysts since their...
An essential application of electron microscopy is to provide feedback to tune the fabrication of na...
International audienceIn situ transmission electron microscopy (TEM) studies of dynamic events produ...
Nanoparticles occur in various environments as a consequence of man-made processes, which raises con...
The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission el...
Scanning transmission electron microscopy (STEM) is an indispensable tool for atomic-resolution stru...
In order to understand how changes to a material at the atomic and nano-scales impact the way a mate...
We describe nNPipe for the automated analysis of morphologically diverse catalyst materials. Automat...
Metallic nanoparticles were analysed with respect to size and shape by a machine learning approach. ...
Phase-contrast transmission electron microscopy (TEM) is a powerful tool for imaging the local atomi...