Observations of the irradiation hardening behavior in neutron irradiated HT-9 steels through in situ TEM nano-mechanical tests

Tanvi Ajantiwalay; Brandon Bohanon; Patrick H. Warren; Megha Dubey; Yaqiao Wu; Janelle P. Wharry; Assel Aitkaliyeva

doi:10.1016/j.jnucmat.2024.155497

Observations of the irradiation hardening behavior in neutron irradiated HT-9 steels through in situ TEM nano-mechanical tests

Tanvi Ajantiwalay, Brandon Bohanon, Patrick H. Warren, Megha Dubey, Yaqiao Wu, Janelle P. Wharry, Assel Aitkaliyeva

Research output: Contribution to journal › Article › peer-review

Abstract

Nano-compression and nano-tensile tests were used to investigate the behavior of HT-9 steel neutron irradiated to 4.29 dpa at 469 °C. The deformation of both as-received and neutron irradiated HT-9 was monitored in situ with a transmission electron microscope, which allowed linking microstructure of the material with the evolution of mechanical properties and identifying the mechanisms governing irradiation-induced hardening of these steels. In nano-compression tests, dislocation-mediated deformation is the deformation mechanism in HT-9 steels irradiated at elevated temperatures. In nano-tensile tests, while dislocations contribute to hardening, grain boundaries determine the deformation mechanisms and eventual fracture of HT-9. The paper further examines the size effect for nano-mechanical tests by varying sample dimensions and comparing obtained results to the micro- and bulk-scale mechanical test data.

Original language	English (US)
Article number	155497
Journal	Journal of Nuclear Materials
Volume	604
DOIs	https://doi.org/10.1016/j.jnucmat.2024.155497
State	Published - Jan 2025
Externally published	Yes

Keywords

Compression test
In-situ transmission electron microscopy
Irradiation effects
Mechanical properties
Tensile test

ASJC Scopus subject areas

Nuclear and High Energy Physics
General Materials Science
Nuclear Energy and Engineering

Online availability

10.1016/j.jnucmat.2024.155497

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title = "Observations of the irradiation hardening behavior in neutron irradiated HT-9 steels through in situ TEM nano-mechanical tests",

abstract = "Nano-compression and nano-tensile tests were used to investigate the behavior of HT-9 steel neutron irradiated to 4.29 dpa at 469 °C. The deformation of both as-received and neutron irradiated HT-9 was monitored in situ with a transmission electron microscope, which allowed linking microstructure of the material with the evolution of mechanical properties and identifying the mechanisms governing irradiation-induced hardening of these steels. In nano-compression tests, dislocation-mediated deformation is the deformation mechanism in HT-9 steels irradiated at elevated temperatures. In nano-tensile tests, while dislocations contribute to hardening, grain boundaries determine the deformation mechanisms and eventual fracture of HT-9. The paper further examines the size effect for nano-mechanical tests by varying sample dimensions and comparing obtained results to the micro- and bulk-scale mechanical test data.",

keywords = "Compression test, In-situ transmission electron microscopy, Irradiation effects, Mechanical properties, Tensile test",

author = "Tanvi Ajantiwalay and Brandon Bohanon and Warren, {Patrick H.} and Megha Dubey and Yaqiao Wu and Wharry, {Janelle P.} and Assel Aitkaliyeva",

note = "This work was funded through the US DOE Office of Nuclear Energy as part of the Nuclear Science User Facilities (NSUF) Rapid Turnaround Experiment (RTE) under awards 20-4138 and 19-1770 . JPW acknowledges support from the National Science Foundation award DMR-1752636 , and PHW was partially supported by the US Nuclear Regulatory Commission grant 31310021M0035 . The authors would like to thank the Center of Advanced Energy Studies (CAES) and Materials and Fuels Complex (MFC), Idaho National Laboratory (INL) for their support and contributions.",

year = "2025",

month = jan,

doi = "10.1016/j.jnucmat.2024.155497",

language = "English (US)",

volume = "604",

journal = "Journal of Nuclear Materials",

issn = "0022-3115",

publisher = "Elsevier B.V.",

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AU - Dubey, Megha

AU - Wu, Yaqiao

AU - Wharry, Janelle P.

AU - Aitkaliyeva, Assel

N1 - This work was funded through the US DOE Office of Nuclear Energy as part of the Nuclear Science User Facilities (NSUF) Rapid Turnaround Experiment (RTE) under awards 20-4138 and 19-1770 . JPW acknowledges support from the National Science Foundation award DMR-1752636 , and PHW was partially supported by the US Nuclear Regulatory Commission grant 31310021M0035 . The authors would like to thank the Center of Advanced Energy Studies (CAES) and Materials and Fuels Complex (MFC), Idaho National Laboratory (INL) for their support and contributions.

PY - 2025/1

Y1 - 2025/1

N2 - Nano-compression and nano-tensile tests were used to investigate the behavior of HT-9 steel neutron irradiated to 4.29 dpa at 469 °C. The deformation of both as-received and neutron irradiated HT-9 was monitored in situ with a transmission electron microscope, which allowed linking microstructure of the material with the evolution of mechanical properties and identifying the mechanisms governing irradiation-induced hardening of these steels. In nano-compression tests, dislocation-mediated deformation is the deformation mechanism in HT-9 steels irradiated at elevated temperatures. In nano-tensile tests, while dislocations contribute to hardening, grain boundaries determine the deformation mechanisms and eventual fracture of HT-9. The paper further examines the size effect for nano-mechanical tests by varying sample dimensions and comparing obtained results to the micro- and bulk-scale mechanical test data.

AB - Nano-compression and nano-tensile tests were used to investigate the behavior of HT-9 steel neutron irradiated to 4.29 dpa at 469 °C. The deformation of both as-received and neutron irradiated HT-9 was monitored in situ with a transmission electron microscope, which allowed linking microstructure of the material with the evolution of mechanical properties and identifying the mechanisms governing irradiation-induced hardening of these steels. In nano-compression tests, dislocation-mediated deformation is the deformation mechanism in HT-9 steels irradiated at elevated temperatures. In nano-tensile tests, while dislocations contribute to hardening, grain boundaries determine the deformation mechanisms and eventual fracture of HT-9. The paper further examines the size effect for nano-mechanical tests by varying sample dimensions and comparing obtained results to the micro- and bulk-scale mechanical test data.

KW - Compression test

KW - In-situ transmission electron microscopy

KW - Irradiation effects

KW - Mechanical properties

KW - Tensile test

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Observations of the irradiation hardening behavior in neutron irradiated HT-9 steels through in situ TEM nano-mechanical tests

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