Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach

Yan Dong; Auriane Etienne; Alex Frolov; Svetlana Fedotova; Katsuhiko Fujii; Koji Fukuya; Constantinos Hatzoglou; Evgenia Kuleshova; Kristina Lindgren; Andrew London; Anabelle Lopez; Sergio Lozano-Perez; Yuichi Miyahara; Yasuyoshi Nagai; Kenji Nishida; Bertrand Radiguet; Daniel K. Schreiber; Naoki Soneda; Mattias Thuvander; Takeshi Toyama; Jing Wang; Faiza Sefta; Peter Chou; Emmanuelle A. Marquis

doi:10.1017/S1431927618015581

Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach

Yan Dong, Auriane Etienne, Alex Frolov, Svetlana Fedotova, Katsuhiko Fujii, Koji Fukuya, Constantinos Hatzoglou, Evgenia Kuleshova, Kristina Lindgren, Andrew London, Anabelle Lopez, Sergio Lozano-Perez, Yuichi Miyahara, Yasuyoshi Nagai, Kenji Nishida, Bertrand Radiguet, Daniel K. Schreiber, Naoki Soneda, Mattias Thuvander, Takeshi ToyamaJing Wang, Faiza Sefta, Peter Chou, Emmanuelle A. Marquis

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22 Citations (Scopus)

Abstract

We summarize the findings from an interlaboratory study conducted between ten international research groups and investigate the use of the commonly used maximum separation distance and local concentration thresholding methods for solute clustering quantification. The study objectives are: to bring clarity to the range of applicability of the methods; identify existing and/or needed modifications; and interpretation of past published data. Participants collected experimental data from a proton-irradiated 304 stainless steel and analyzed Cu-rich and Ni-Si rich clusters. The datasets were also analyzed by one researcher to clarify variability originating from different operators. The Cu distribution fulfills the ideal requirements of the maximum separation method (MSM), namely a dilute matrix Cu concentration and concentrated Cu clusters. This enabled a relatively tight distribution of the cluster number density among the participants. By contrast, the group analysis of the Ni-Si rich clusters by the MSM was complicated by a high Ni matrix concentration and by the presence of Si-decorated dislocations, leading to larger variability among researchers. While local concentration filtering could, in principle, tighten the results, the cluster identification step inevitably maintained a high scatter. Recommendations regarding reporting, selection of analysis method, and expected variability when interpreting published data are discussed.

Original language	English
Pages (from-to)	356-366
Number of pages	11
Journal	Microscopy and Microanalysis
Volume	25
Issue number	2
DOIs	https://doi.org/10.1017/S1431927618015581
Publication status	Published - 2019 Apr 1

Keywords

cluster analysis
maximum separation
satom probe tomography

ASJC Scopus subject areas

Instrumentation

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Dong, Y., Etienne, A., Frolov, A., Fedotova, S., Fujii, K., Fukuya, K., Hatzoglou, C., Kuleshova, E., Lindgren, K., London, A., Lopez, A., Lozano-Perez, S., Miyahara, Y., Nagai, Y., Nishida, K., Radiguet, B., Schreiber, D. K., Soneda, N., Thuvander, M., ... Marquis, E. A. (2019). Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach. Microscopy and Microanalysis, 25(2), 356-366. https://doi.org/10.1017/S1431927618015581

Dong, Y, Etienne, A, Frolov, A, Fedotova, S, Fujii, K, Fukuya, K, Hatzoglou, C, Kuleshova, E, Lindgren, K, London, A, Lopez, A, Lozano-Perez, S, Miyahara, Y, Nagai, Y, Nishida, K, Radiguet, B, Schreiber, DK, Soneda, N, Thuvander, M, Toyama, T, Wang, J, Sefta, F, Chou, P & Marquis, EA 2019, 'Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach', Microscopy and Microanalysis, vol. 25, no. 2, pp. 356-366. https://doi.org/10.1017/S1431927618015581

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title = "Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach",

abstract = "We summarize the findings from an interlaboratory study conducted between ten international research groups and investigate the use of the commonly used maximum separation distance and local concentration thresholding methods for solute clustering quantification. The study objectives are: to bring clarity to the range of applicability of the methods; identify existing and/or needed modifications; and interpretation of past published data. Participants collected experimental data from a proton-irradiated 304 stainless steel and analyzed Cu-rich and Ni-Si rich clusters. The datasets were also analyzed by one researcher to clarify variability originating from different operators. The Cu distribution fulfills the ideal requirements of the maximum separation method (MSM), namely a dilute matrix Cu concentration and concentrated Cu clusters. This enabled a relatively tight distribution of the cluster number density among the participants. By contrast, the group analysis of the Ni-Si rich clusters by the MSM was complicated by a high Ni matrix concentration and by the presence of Si-decorated dislocations, leading to larger variability among researchers. While local concentration filtering could, in principle, tighten the results, the cluster identification step inevitably maintained a high scatter. Recommendations regarding reporting, selection of analysis method, and expected variability when interpreting published data are discussed.",

keywords = "cluster analysis, maximum separation, satom probe tomography",

author = "Yan Dong and Auriane Etienne and Alex Frolov and Svetlana Fedotova and Katsuhiko Fujii and Koji Fukuya and Constantinos Hatzoglou and Evgenia Kuleshova and Kristina Lindgren and Andrew London and Anabelle Lopez and Sergio Lozano-Perez and Yuichi Miyahara and Yasuyoshi Nagai and Kenji Nishida and Bertrand Radiguet and Schreiber, {Daniel K.} and Naoki Soneda and Mattias Thuvander and Takeshi Toyama and Jing Wang and Faiza Sefta and Peter Chou and Marquis, {Emmanuelle A.}",

note = "Funding Information: The voluntary participation by most members of the APT interlaboratory study, financial support of EPRI and EDF-MAI for the analysis of the aggregate results and preparation of the samples at the University of Michigan, Gary Was at the University of Michigan for providing the proton irradiated sample, and Allen Hunter at Publisher Copyright: Copyright {\textcopyright} Microscopy Society of America 2019.",

year = "2019",

month = apr,

day = "1",

doi = "10.1017/S1431927618015581",

language = "English",

volume = "25",

pages = "356--366",

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T1 - Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach

AU - Dong, Yan

AU - Etienne, Auriane

AU - Frolov, Alex

AU - Fedotova, Svetlana

AU - Fujii, Katsuhiko

AU - Fukuya, Koji

AU - Hatzoglou, Constantinos

AU - Kuleshova, Evgenia

AU - Lindgren, Kristina

AU - London, Andrew

AU - Lopez, Anabelle

AU - Lozano-Perez, Sergio

AU - Miyahara, Yuichi

AU - Nagai, Yasuyoshi

AU - Nishida, Kenji

AU - Radiguet, Bertrand

AU - Schreiber, Daniel K.

AU - Soneda, Naoki

AU - Thuvander, Mattias

AU - Toyama, Takeshi

AU - Wang, Jing

AU - Sefta, Faiza

AU - Chou, Peter

AU - Marquis, Emmanuelle A.

N1 - Funding Information: The voluntary participation by most members of the APT interlaboratory study, financial support of EPRI and EDF-MAI for the analysis of the aggregate results and preparation of the samples at the University of Michigan, Gary Was at the University of Michigan for providing the proton irradiated sample, and Allen Hunter at Publisher Copyright: Copyright © Microscopy Society of America 2019.

PY - 2019/4/1

Y1 - 2019/4/1

N2 - We summarize the findings from an interlaboratory study conducted between ten international research groups and investigate the use of the commonly used maximum separation distance and local concentration thresholding methods for solute clustering quantification. The study objectives are: to bring clarity to the range of applicability of the methods; identify existing and/or needed modifications; and interpretation of past published data. Participants collected experimental data from a proton-irradiated 304 stainless steel and analyzed Cu-rich and Ni-Si rich clusters. The datasets were also analyzed by one researcher to clarify variability originating from different operators. The Cu distribution fulfills the ideal requirements of the maximum separation method (MSM), namely a dilute matrix Cu concentration and concentrated Cu clusters. This enabled a relatively tight distribution of the cluster number density among the participants. By contrast, the group analysis of the Ni-Si rich clusters by the MSM was complicated by a high Ni matrix concentration and by the presence of Si-decorated dislocations, leading to larger variability among researchers. While local concentration filtering could, in principle, tighten the results, the cluster identification step inevitably maintained a high scatter. Recommendations regarding reporting, selection of analysis method, and expected variability when interpreting published data are discussed.

AB - We summarize the findings from an interlaboratory study conducted between ten international research groups and investigate the use of the commonly used maximum separation distance and local concentration thresholding methods for solute clustering quantification. The study objectives are: to bring clarity to the range of applicability of the methods; identify existing and/or needed modifications; and interpretation of past published data. Participants collected experimental data from a proton-irradiated 304 stainless steel and analyzed Cu-rich and Ni-Si rich clusters. The datasets were also analyzed by one researcher to clarify variability originating from different operators. The Cu distribution fulfills the ideal requirements of the maximum separation method (MSM), namely a dilute matrix Cu concentration and concentrated Cu clusters. This enabled a relatively tight distribution of the cluster number density among the participants. By contrast, the group analysis of the Ni-Si rich clusters by the MSM was complicated by a high Ni matrix concentration and by the presence of Si-decorated dislocations, leading to larger variability among researchers. While local concentration filtering could, in principle, tighten the results, the cluster identification step inevitably maintained a high scatter. Recommendations regarding reporting, selection of analysis method, and expected variability when interpreting published data are discussed.

KW - cluster analysis

KW - maximum separation

KW - satom probe tomography

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JF - Microscopy and Microanalysis

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ER -

Atom Probe Tomography Interlaboratory Study on Clustering Analysis in Experimental Data Using the Maximum Separation Distance Approach

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Keywords

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