AI Article Synopsis
- Transmission electron microscopy (TEM) is essential in heterogeneous catalysis for measuring the size of metal nanoparticles, but current methods rely on spherical assumptions that limit accuracy.
- Cycle-consistent generative adversarial networks (CycleGANs) are proposed as a solution to connect experimental TEM images with their atomic structure, enhancing the extraction of meaningful data.
- A new network developed for estimating nanoparticle size can accurately assess ≈70% of observed particles, paving the way for more precise characterization of catalytic materials by overcoming limitations of traditional techniques.
Article Abstract
Transmission electron microscopy (TEM) plays a crucial role in heterogeneous catalysis for assessing the size distribution of supported metal nanoparticles. Typically, nanoparticle size is quantified by measuring the diameter under the assumption of spherical geometry, a simplification that limits the precision needed for advancing synthesis-structure-performance relationships. Currently, there is a lack of techniques that can reliably extract more meaningful information from atomically resolved TEM images, like nuclearity or geometry. Here, cycle-consistent generative adversarial networks (CycleGANs) are explored to bridge experimental and simulated images, directly linking experimental observations with information from their underlying atomic structure. Using the versatile Pt/CeO (Pt particles centered ≈2 nm) catalyst synthesized by impregnation, large datasets of experimental scanning transmission electron micrographs and physical image simulations are created to train a CycleGAN. A subsequent size-estimation network is developed to determine the nuclearity of imaged nanoparticles, providing plausible estimates for ≈70% of experimentally observed particles. This automatic approach enables precise size determination of supported nanoparticle-based catalysts overcoming crystal orientation limitations of conventional techniques, promising high accuracy with sufficient training data. Tools like this are envisioned to be of great use in designing and characterizing catalytic materials with improved atomic precision.
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| http://dx.doi.org/10.1002/smtd.202401108 | DOI Listing |
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