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Autori principali: Lee, Chang-Gi, Chae, Byeong-Gyu, Ro, I-Jun, Jang, Kyuseon, Woods, Eric, Ahn, Jaemin, Park, Seong Yong, Gault, Baptiste, Kim, Se-Ho
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.10506
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author Lee, Chang-Gi
Chae, Byeong-Gyu
Ro, I-Jun
Jang, Kyuseon
Woods, Eric
Ahn, Jaemin
Park, Seong Yong
Gault, Baptiste
Kim, Se-Ho
author_facet Lee, Chang-Gi
Chae, Byeong-Gyu
Ro, I-Jun
Jang, Kyuseon
Woods, Eric
Ahn, Jaemin
Park, Seong Yong
Gault, Baptiste
Kim, Se-Ho
contents Atom probe tomography (APT) enables near atomic scale three dimensional elemental mapping through the controlled field evaporation of surface atoms triggered by the combined application of a DC voltage and either voltage or laser pulses. As the selected laser wavelength for the atom probes transitioned from the near-infrared (1050 nm) to shorter wavelengths e.g., green (532 nm) and near ultraviolet, the quality of data improved and the range of materials amenable for analysis broadened. A new commercial laser atom probe with a wavelength of 257.5 nm, referred to as deep ultraviolet (DUV), has been recently launched. However, the effects of DUV lasers on different classes of materials have not yet been systematically investigated. In this study, a range of materials, including metals, semiconductor, and oxides, have been examined using commercial atom probes with different laser wavelengths but in principle comparable particle detection system. The quality of the NUV and DUV laser atom probe data is evaluated based on four key metrics: background, detection events, ion detection histogram, and mass-resolving power. Furthermore, the application of a thin coating to the finished APT specimens enhances the data quality for both laser wavelengths.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10506
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Performance Evaluation of Deep,Near Ultraviolet Laser Assisted Atom Probes for a range of Material system
Lee, Chang-Gi
Chae, Byeong-Gyu
Ro, I-Jun
Jang, Kyuseon
Woods, Eric
Ahn, Jaemin
Park, Seong Yong
Gault, Baptiste
Kim, Se-Ho
Materials Science
Atom probe tomography (APT) enables near atomic scale three dimensional elemental mapping through the controlled field evaporation of surface atoms triggered by the combined application of a DC voltage and either voltage or laser pulses. As the selected laser wavelength for the atom probes transitioned from the near-infrared (1050 nm) to shorter wavelengths e.g., green (532 nm) and near ultraviolet, the quality of data improved and the range of materials amenable for analysis broadened. A new commercial laser atom probe with a wavelength of 257.5 nm, referred to as deep ultraviolet (DUV), has been recently launched. However, the effects of DUV lasers on different classes of materials have not yet been systematically investigated. In this study, a range of materials, including metals, semiconductor, and oxides, have been examined using commercial atom probes with different laser wavelengths but in principle comparable particle detection system. The quality of the NUV and DUV laser atom probe data is evaluated based on four key metrics: background, detection events, ion detection histogram, and mass-resolving power. Furthermore, the application of a thin coating to the finished APT specimens enhances the data quality for both laser wavelengths.
title Performance Evaluation of Deep,Near Ultraviolet Laser Assisted Atom Probes for a range of Material system
topic Materials Science
url https://arxiv.org/abs/2411.10506