Radiation damage suppression in AISI-316 steel nanoparticles: Implications for the design of future nuclear materials

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Radiation damage suppression in AISI-316 steel nanoparticles: Implications for the design of future nuclear materials. / Aradi, Emily; Tunes, Matheus A.; Lewis-Fell, Jacob et al.
In: ACS Applied Nano Materials, Vol. 3, No. 10, 23.10.2020, p. 9652-9662.

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@article{999dae0062b7450880f71e9a70a73119,
title = "Radiation damage suppression in AISI-316 steel nanoparticles: Implications for the design of future nuclear materials",
abstract = "The self-healing capability of point and extended defects that are introduced by energetic particle irradiation is a desired behavior to be attained in the design and selection in potential materials for application in extreme environments. Nanoporous materials have a potential for achieving higher radiation tolerance due to the presence of many active unsaturable surfaces to which defects may diffuse and thus be effectively annihilated. The effects of heavy ion collisions in the lattice of functional AISI-316 steel nanoparticles (NPs)-which serve as a model for the ligaments in a nanoporous-are herein investigated in situ within a transmission electron microscope. Comparisons are made directly with AISI-316 steel in the form of foils, and the results show that the fewer radiation-induced defect clusters form in the NPs and that small NPs (r < 50 nm) were observed to accumulate fewer defects when compared to larger NPs. Post-irradiation analytical characterization within a scanning transmission electron microscope revealed that the AISI-316 steel NPs may develop a radiation-induced self-passivation driven by a solute-drag mechanism: an effect that can potentially enhance their radiation corrosion resistance in the expected extreme conditions of a reactor. The capability of an NP to self-heal irradiation-induced point defects is investigated using the cellular model for active internal and surface sinks. The design of functional nanoscale materials for extreme environments is discussed.",
keywords = "Ion irradiation, Nanoparticles, Nanoporous materials, Radiation damage, Transmission electron microscopy",
author = "Emily Aradi and Tunes, {Matheus A.} and Jacob Lewis-Fell and Graeme Greaves and Helmut Antrekowitsch and Stefan Pogatscher and Donnelly, {Stephen E.} and Hinks, {Jonathan A.}",
year = "2020",
month = oct,
day = "23",
doi = "10.1021/acsanm.0c01611",
language = "English",
volume = "3",
pages = "9652--9662",
journal = "ACS Applied Nano Materials",
issn = "2574-0970",
publisher = "American Chemical Society",
number = "10",

}

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TY - JOUR

T1 - Radiation damage suppression in AISI-316 steel nanoparticles

T2 - Implications for the design of future nuclear materials

AU - Aradi, Emily

AU - Tunes, Matheus A.

AU - Lewis-Fell, Jacob

AU - Greaves, Graeme

AU - Antrekowitsch, Helmut

AU - Pogatscher, Stefan

AU - Donnelly, Stephen E.

AU - Hinks, Jonathan A.

PY - 2020/10/23

Y1 - 2020/10/23

N2 - The self-healing capability of point and extended defects that are introduced by energetic particle irradiation is a desired behavior to be attained in the design and selection in potential materials for application in extreme environments. Nanoporous materials have a potential for achieving higher radiation tolerance due to the presence of many active unsaturable surfaces to which defects may diffuse and thus be effectively annihilated. The effects of heavy ion collisions in the lattice of functional AISI-316 steel nanoparticles (NPs)-which serve as a model for the ligaments in a nanoporous-are herein investigated in situ within a transmission electron microscope. Comparisons are made directly with AISI-316 steel in the form of foils, and the results show that the fewer radiation-induced defect clusters form in the NPs and that small NPs (r < 50 nm) were observed to accumulate fewer defects when compared to larger NPs. Post-irradiation analytical characterization within a scanning transmission electron microscope revealed that the AISI-316 steel NPs may develop a radiation-induced self-passivation driven by a solute-drag mechanism: an effect that can potentially enhance their radiation corrosion resistance in the expected extreme conditions of a reactor. The capability of an NP to self-heal irradiation-induced point defects is investigated using the cellular model for active internal and surface sinks. The design of functional nanoscale materials for extreme environments is discussed.

AB - The self-healing capability of point and extended defects that are introduced by energetic particle irradiation is a desired behavior to be attained in the design and selection in potential materials for application in extreme environments. Nanoporous materials have a potential for achieving higher radiation tolerance due to the presence of many active unsaturable surfaces to which defects may diffuse and thus be effectively annihilated. The effects of heavy ion collisions in the lattice of functional AISI-316 steel nanoparticles (NPs)-which serve as a model for the ligaments in a nanoporous-are herein investigated in situ within a transmission electron microscope. Comparisons are made directly with AISI-316 steel in the form of foils, and the results show that the fewer radiation-induced defect clusters form in the NPs and that small NPs (r < 50 nm) were observed to accumulate fewer defects when compared to larger NPs. Post-irradiation analytical characterization within a scanning transmission electron microscope revealed that the AISI-316 steel NPs may develop a radiation-induced self-passivation driven by a solute-drag mechanism: an effect that can potentially enhance their radiation corrosion resistance in the expected extreme conditions of a reactor. The capability of an NP to self-heal irradiation-induced point defects is investigated using the cellular model for active internal and surface sinks. The design of functional nanoscale materials for extreme environments is discussed.

KW - Ion irradiation

KW - Nanoparticles

KW - Nanoporous materials

KW - Radiation damage

KW - Transmission electron microscopy

UR - http://www.scopus.com/inward/record.url?scp=85094214400&partnerID=8YFLogxK

U2 - 10.1021/acsanm.0c01611

DO - 10.1021/acsanm.0c01611

M3 - Article

AN - SCOPUS:85094214400

VL - 3

SP - 9652

EP - 9662

JO - ACS Applied Nano Materials

JF - ACS Applied Nano Materials

SN - 2574-0970

IS - 10

ER -