Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel

Brittany Muntifering; Rémi Dingreville; Khalid Hattar; Jianmin Qu

doi:10.1557/opl.2015.499

Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel

Brittany Muntifering, Rémi Dingreville, Khalid Hattar, Jianmin Qu

Northwestern University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

7 Scopus citations

Abstract

Transmission electron microscopy (TEM) is a valuable methodology for investigating radiation-induced microstructural changes and elucidating the underlying mechanisms involved in the aging and degradation of nuclear reactor materials. However, the use of electrons for imaging may result in several inadvertent effects that can potentially change the microstructure and mechanisms active in the material being investigated. In this study, in situ TEM characterization is performed on nanocrystalline nickel samples under self-ion irradiation and post irradiation annealing. During annealing, voids are formed around 200 °C only in the area illuminated by the electron beam. Based on diffraction patterns analyses, it is hypothesized that the electron beam enhanced the growth of a NiO layer resulting in a decrease of vacancy mobility during annealing. The electron beam used to investigate self-ion irradiation ultimately significantly affected the type of defects formed and the final defect microstructure.

Original language	English
Title of host publication	Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials
Editors	David Andersson, Yongfeng Zhang, Chaitanya Deo, Frederic Soisson
Pages	13-18
Number of pages	6
ISBN (Electronic)	9781510826618
DOIs	https://doi.org/10.1557/opl.2015.499
State	Published - 2015
Event	2015 MRS Spring Meeting - San Francisco, United States Duration: 6 Apr 2015 → 10 Apr 2015

Publication series

Name	Materials Research Society Symposium Proceedings
Volume	1809
ISSN (Print)	0272-9172

Conference

Conference	2015 MRS Spring Meeting
Country/Territory	United States
City	San Francisco
Period	6/04/15 → 10/04/15

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Muntifering, B., Dingreville, R., Hattar, K., & Qu, J. (2015). Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel. In D. Andersson, Y. Zhang, C. Deo, & F. Soisson (Eds.), Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials (pp. 13-18). (Materials Research Society Symposium Proceedings; Vol. 1809). https://doi.org/10.1557/opl.2015.499

Muntifering, Brittany ; Dingreville, Rémi ; Hattar, Khalid et al. / Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel. Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials. editor / David Andersson ; Yongfeng Zhang ; Chaitanya Deo ; Frederic Soisson. 2015. pp. 13-18 (Materials Research Society Symposium Proceedings).

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title = "Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel",

abstract = "Transmission electron microscopy (TEM) is a valuable methodology for investigating radiation-induced microstructural changes and elucidating the underlying mechanisms involved in the aging and degradation of nuclear reactor materials. However, the use of electrons for imaging may result in several inadvertent effects that can potentially change the microstructure and mechanisms active in the material being investigated. In this study, in situ TEM characterization is performed on nanocrystalline nickel samples under self-ion irradiation and post irradiation annealing. During annealing, voids are formed around 200 °C only in the area illuminated by the electron beam. Based on diffraction patterns analyses, it is hypothesized that the electron beam enhanced the growth of a NiO layer resulting in a decrease of vacancy mobility during annealing. The electron beam used to investigate self-ion irradiation ultimately significantly affected the type of defects formed and the final defect microstructure.",

author = "Brittany Muntifering and R{\'e}mi Dingreville and Khalid Hattar and Jianmin Qu",

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doi = "10.1557/opl.2015.499",

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Muntifering, B, Dingreville, R, Hattar, K & Qu, J 2015, Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel. in D Andersson, Y Zhang, C Deo & F Soisson (eds), Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials. Materials Research Society Symposium Proceedings, vol. 1809, pp. 13-18, 2015 MRS Spring Meeting, San Francisco, United States, 6/04/15. https://doi.org/10.1557/opl.2015.499

Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel. / Muntifering, Brittany; Dingreville, Rémi; Hattar, Khalid et al.
Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials. ed. / David Andersson; Yongfeng Zhang; Chaitanya Deo; Frederic Soisson. 2015. p. 13-18 (Materials Research Society Symposium Proceedings; Vol. 1809).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel

AU - Muntifering, Brittany

AU - Dingreville, Rémi

AU - Hattar, Khalid

AU - Qu, Jianmin

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N2 - Transmission electron microscopy (TEM) is a valuable methodology for investigating radiation-induced microstructural changes and elucidating the underlying mechanisms involved in the aging and degradation of nuclear reactor materials. However, the use of electrons for imaging may result in several inadvertent effects that can potentially change the microstructure and mechanisms active in the material being investigated. In this study, in situ TEM characterization is performed on nanocrystalline nickel samples under self-ion irradiation and post irradiation annealing. During annealing, voids are formed around 200 °C only in the area illuminated by the electron beam. Based on diffraction patterns analyses, it is hypothesized that the electron beam enhanced the growth of a NiO layer resulting in a decrease of vacancy mobility during annealing. The electron beam used to investigate self-ion irradiation ultimately significantly affected the type of defects formed and the final defect microstructure.

AB - Transmission electron microscopy (TEM) is a valuable methodology for investigating radiation-induced microstructural changes and elucidating the underlying mechanisms involved in the aging and degradation of nuclear reactor materials. However, the use of electrons for imaging may result in several inadvertent effects that can potentially change the microstructure and mechanisms active in the material being investigated. In this study, in situ TEM characterization is performed on nanocrystalline nickel samples under self-ion irradiation and post irradiation annealing. During annealing, voids are formed around 200 °C only in the area illuminated by the electron beam. Based on diffraction patterns analyses, it is hypothesized that the electron beam enhanced the growth of a NiO layer resulting in a decrease of vacancy mobility during annealing. The electron beam used to investigate self-ion irradiation ultimately significantly affected the type of defects formed and the final defect microstructure.

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BT - Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials

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Muntifering B, Dingreville R, Hattar K, Qu J. Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel. In Andersson D, Zhang Y, Deo C, Soisson F, editors, Multiscale Modeling and Experiments on Microstructural Evolution in Nuclear Materials. 2015. p. 13-18. (Materials Research Society Symposium Proceedings). doi: 10.1557/opl.2015.499

Electron beam effects during in-situ annealing of self-ion irradiated nanocrystalline nickel

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