Nanoindentation and in situ microcompression in different dose regimes of proton beam irradiated 304 SS

Reichardt, Ashley; Lupinacci, A.; Frazer, D.; Bailey, N.; Vo, H.T.; Howard, C.; Jiao, Zhijie; Minor, AM; Chou, Peter; Hosemann, Peter

doi:10.1016/j.jnucmat.2017.01.036

Cited by 49 publications

(11 citation statements)

References 27 publications

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“…(c) Size dependence of the shear stress at 1% engineering strain measured from micropillars. Shear stress from submicron pillars deformed in TEM is plotted together with previously published results of in situ SEM testing with the same bulk material (red squares)[18] and other FCC materials data[19,20,[23][24][25].…”

mentioning

confidence: 99%

Dislocation plasticity in FeCoCrMnNi high-entropy alloy: quantitative insights from in situ transmission electron microscopy deformation

Lee

Duarte

Feuerbacher

et al. 2020

Materials Research Letters

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The mechanical properties of high-entropy alloys (HEAs) are still not deeply understood. Detailed knowledge of the strengthening mechanism, especially, the atomistic origin of solid solution hardening and its interplay with dislocation plasticity is needed. Here, we report on the dislocation glide behavior of a FeCoCrNiMn face-centered cubic (FCC) single crystal studied by in situ deformation in a transmission electron microscope (TEM). The threshold shear stress for dislocation glide in a thin foil is measured from dislocation curvature as exceeding 400 MPa. Interestingly, dislocations are prevented from straightening upon unloading due to high frictional stresses. IMPACT STATEMENT The fiction stress for dislocation glide in a FeCoCrMnNi HEA is assessed by direct measurement of dislocation line curvature during in situ TEM deformation, which is higher compared to other FCC metals, explaining the outstanding yield and flow stress of the HEA.

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mentioning

confidence: 99%

Dislocation plasticity in FeCoCrMnNi high-entropy alloy: quantitative insights from in situ transmission electron microscopy deformation

Lee

Duarte

Feuerbacher

et al. 2020

Materials Research Letters

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“…Nanoindentation hardness results shown in Figure 3 and Table 2 demonstrate that ion irradiation can result in the increase of hardness and the magnitude of irradiation hardening increases with the irradiation dose. Many previous studies have been conducted on the irradiation hardening of different materials, including CLAM steel [9,10,[14][15][16][17][18][19][20][21][22]64]. Generally, by neglecting the effects of implanted ions [64], it is attributed to the fact that irradiation-induced defects such as dislocation loops impede the glide of dislocations and can be quantified by the dispersed barrier model [5,19,21]: Since the nanoindentation hardness can be related to yield strength through the Tabor relation [66], one can express the increase of hardness induced by irradiation as:…”

Section: Irradiation Hardeningmentioning

confidence: 99%

“…Depth-dependent hardness can be directly attained through Continuous Stiffness Measurement [13]. In recent years, a large number of nanoindentation tests have been conducted to investigate the irradiation hardening of metallic materials [9,10,[14][15][16][17][18][19][20][21][22]. Meanwhile, several methods have been developed to obtain nanoindentation creep behavior, including constant rate of loading method [23], constant depth method [24], constant strain rate method [25], constant load method [26], and rate jump method [27].…”

Section: Introductionmentioning

confidence: 99%

Hardening and Creep of Ion Irradiated CLAM Steel by Nanoindentation

Liu

et al. 2020

Crystals

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Ion irradiation, combined with nanoindentation, has long been recognized as an effective way to study effects of irradiation on the mechanical properties of metallic materials. In this research, hardening and creep of ion irradiated Chinese low activation martensitic (CLAM) steel are investigated by nanoindentation. Firstly, it is demonstrated that ion irradiation results in the increase of hardness, because irradiation-induced defects impede the glide of dislocations. Secondly, the unirradiated CLAM steel shows indentation creep size effect (ICSE) that the indentation creep strain decreases with the applied load, and ICSE is found to be associated with the variations of geometrical necessary dislocations (GNDs) density. However, ion irradiation results in the alleviation of ICSE due to the irradiation hardening. Thirdly, ion irradiation accelerates nanoindentation creep due to the large numbers of irradiation-induced vacancies whose diffusion controls creep deformation. Meanwhile, owing to the annihilation of vacancies, ion irradiation has a significant influence on the primary creep while only negligible influence has been observed for the steady-state creep.

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“…The spatial extent of radiation-induced segregation (RIS) at grain boundaries, the hardening, and the defect types and densities were all similar; this proof of principle study has led to a large number of proton irradiation studies. These include studies of radiationinduced interstitial/vacancy defect clusters [17][18][19][20][21][22], precipitation [21][22][23][24][25] and segregation [18,19,22,26], and mechanical changes [15,20,[22][23][24]27]; irradiation assisted stress corrosion cracking has also been studied extensively using proton irradiation [22,28,29]. Studies have also continued to compare proton irradiation to neutron irradiation experiments [17,22].…”

Section: -Introductionmentioning

confidence: 99%

Microstructural examination of neutron, proton and self-ion irradiation damage in a model Fe9Cr alloy

Haley

Shubeita

Wady

et al. 2020

Journal of Nuclear Materials

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Transmission electron microscopy (TEM) was used to compare the microstructural defects produced in an Fe9Cr model alloy during exposure to neutrons, protons, or self-ions. Samples from the same model alloy were irradiated using fission-neutrons, 2MeV Fe+ ions or 1.2MeV protons at similar temperatures (~300°C) and similar doses (~2.0dpa). The neutron-irradiated alloy contained visible interstitial dislocation loops with b=〈111〉, and on average ~5nm in size. The density varied from 2±1x10 20 m -3 (in the matrix far from dislocations and boundaries) to 1.2±0.3x10 23 m -3 (close to helical dislocation lines). Chromium α'-phase precipitates were also identified at a density of 7.4±0.4x10 23 m -3 . Self-ion irradiation produced mostly homogeneously distributed dislocation loops (6-7nm on average), and with a greater fraction of 〈100〉 loops (~40%) than was seen in the neutron-irradiated alloy, and at a density of 6.8±0.8 x10 22 m -3 . In contrast to the loops produced by neutron irradiation, the self-ion irradiated Fe9Cr contained only vacancy-type loops. Chromium also remained in solution. Proton-irradiated Fe9Cr contained interstitial dislocation loops close to helical-dislocation segments, similar to the neutron-irradiated sample. Chromium α'-phases were also identified in the proton-irradiated sample at a density of 2.5±0.3x10 23 m -3 , and large voids (up to 7nm) were found at a density over 10 22 m -3 . Like the neutron-irradiated sample, the density of dislocation loops was also heterogeneously distributed; far from grain boundaries and dislocation lines the density was 2.5±0.4 x10 22 m -3 , while close to helical dislocation lines the density was 8.1±1.3 x10 22 m -3 .

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Nanoindentation and in situ microcompression in different dose regimes of proton beam irradiated 304 SS

Cited by 49 publications

References 27 publications

Dislocation plasticity in FeCoCrMnNi high-entropy alloy: quantitative insights from in situ transmission electron microscopy deformation

Dislocation plasticity in FeCoCrMnNi high-entropy alloy: quantitative insights from in situ transmission electron microscopy deformation

Hardening and Creep of Ion Irradiated CLAM Steel by Nanoindentation

Microstructural examination of neutron, proton and self-ion irradiation damage in a model Fe9Cr alloy

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