In situ study of the initiation of hydrogen bubbles at the aluminium metal/oxide interface

Xie, Degang; Wang, Zhangjie; Sun, Jun; Li, Ju; Ma, Evan; Shan, Zhiwei

doi:10.1038/nmat4336

Cited by 143 publications

(87 citation statements)

References 28 publications

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“…3b,c, two minor changes can be observed by comparing the image before and after the hydrogenation: tiny blisters appeared on the pillar surface (as indicated by black arrows) and a short curved dislocation segment became straight (as indicated by the white arrow). The former unequivocally proves that hydrogen has been introduced into the aluminium pillar29. The latter, on the other hand, cannot be simply attributed to the effect of hydrogen, considering that straightening of dislocation also occurred in the previous vacuum aging experiment (Fig.…”

Section: Resultsmentioning

confidence: 73%

“…The compression tests were carried out subsequently in vacuum and ∼2 Pa pure hydrogen gas. Before the tests in hydrogen environment, samples were hydrogenated under electron-beam intensity of ∼0.45 nA μm −2 in ∼2 Pa H 2 for about 30 min, which is long enough for hydrogen diffusion while not too long to cause obvious blistering on the pillar surface29. The dislocations inside the pillar roughly keep the same configuration during the charging process.…”

Section: Methodsmentioning

confidence: 99%

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Hydrogenated vacancies lock dislocations in aluminium

Xie

et al. 2016

Nat Commun

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145

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Due to its high diffusivity, hydrogen is often considered a weak inhibitor or even a promoter of dislocation movements in metals and alloys. By quantitative mechanical tests in an environmental transmission electron microscope, here we demonstrate that after exposing aluminium to hydrogen, mobile dislocations can lose mobility, with activating stress more than doubled. On degassing, the locked dislocations can be reactivated under cyclic loading to move in a stick-slip manner. However, relocking the dislocations thereafter requires a surprisingly long waiting time of ∼103 s, much longer than that expected from hydrogen interstitial diffusion. Both the observed slow relocking and strong locking strength can be attributed to superabundant hydrogenated vacancies, verified by our atomistic calculations. Vacancies therefore could be a key plastic flow localization agent as well as damage agent in hydrogen environment.

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Section: Resultsmentioning

confidence: 73%

Section: Methodsmentioning

confidence: 99%

Hydrogenated vacancies lock dislocations in aluminium

Xie

et al. 2016

Nat Commun

Self Cite

145

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“…Xie et al . 37 reported an in-situ observation of nanoscale gas bubbles at aluminium metal/oxide interface under the exposure of hydrogen in order to explain the commonly observed interfacial failure. Pruymboom et al .…”

Section: Resultsmentioning

confidence: 99%

Nanometre-scale 3D defects in Cr2AlC thin films

Chen

Mušić

Shang

et al. 2017

Sci Rep

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MAX-phase Cr2AlC containing thin films were synthesized by magnetron sputtering in an industrial system. Nanometre-scale 3D defects are observed near the boundary between regions of Cr2AlC and of the disordered solid solution (CrAl)xCy. Shrinkage of the Cr-Cr interplanar distance and elongation of the Cr-Al distance in the vicinity of the defects are detected using transmission electron microscopy. The here observed deformation surrounding the defects was described using density functional theory by comparing the DOS of bulk Cr2AlC with the DOS of a strained and unstrained Cr2AlC(0001) surface. From the partial density of states analysis, it can be learned that Cr-C bonds are stronger than Cr-Al bonds in bulk Cr2AlC. Upon Cr2AlC(0001) surface formation, both bonds are weakened. While the Cr-C bonds recover their bulk strength as Cr2AlC(0001) is strained, the Cr-Al bonds experience only a partial recovery, still being weaker than their bulk counterparts. Hence, the strain induced bond strengthening in Cr2AlC(0001) is larger for Cr d – C p bonds than for Cr d – Al p bonds. The here observed changes in bonding due to the formation of a strained surface are consistent with the experimentally observed elongation of the Cr-Al distance in the vicinity of nm-scale 3D defects in Cr2AlC thin films.

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“…3–4 The design of in situ TEM holders have now progressed to the level that both strength and ductility can be quantified through compression, tension or bending experiments at low (−140 °C) or high (400 °C) temperatures. 5 It is now possible to make high resolution force measurement and control system. These, combined with improve sample geometries lead to new loading mechanisms, and new methods to measure stress and strain locally.…”

Section: Current Statusmentioning

confidence: 99%

“…For example, the Delft group has used electron energy-loss spectroscopy (EELS) to measure local temperature, using change of gas density with temperature in windowed holder filled with 1.2 5 Pa of H 2 . 44 Resistivity measurements as implemented in the Delft-MEMS based holders seem to work quite well.…”

Section: Future Development Needsmentioning

confidence: 99%

Current status and future directions for in situ transmission electron microscopy

et al. 2016

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This review article discusses the current and future possibilities for the application of in situ transmission electron microscopy to reveal synthesis pathways and functional mechanisms in complex and nanoscale materials. The findings of a group of scientists, representing academia, government labs and private sector entities (predominantly commercial vendors) during a workshop, held at the Center for Nanoscale Science and Technology- National Institute of Science and Technology (CNST-NIST), are discussed. We provide a comprehensive review of the scientific needs and future instrument and technique developments required to meet them.

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In situ study of the initiation of hydrogen bubbles at the aluminium metal/oxide interface

Cited by 143 publications

References 28 publications

Hydrogenated vacancies lock dislocations in aluminium

Hydrogenated vacancies lock dislocations in aluminium

Nanometre-scale 3D defects in Cr2AlC thin films

Current status and future directions for in situ transmission electron microscopy

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