Predictive model of hydrogen trapping and bubbling in nanovoids in bcc metals

Hou, Jie; Kong, Xiang-Shan; Wu, Xue-Bing; Song, Jun; Liu, C. S.

doi:10.1038/s41563-019-0422-4

Cited by 94 publications

(58 citation statements)

References 61 publications

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“…anosized voids, including pores, cavities, and bubbles, are common defects found in materials 1 . Voids can be generated under a variety of service conditions and are most often detrimental to the material's structural properties.…”

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confidence: 99%

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

et al. 2020

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Quantifying chemical compositions around nanovoids is a fundamental task for research and development of various materials. Atom probe tomography (APT) and scanning transmission electron microscopy (STEM) are currently the most suitable tools because of their ability to probe materials at the nanoscale. Both techniques have limitations, particularly APT, because of insufficient understanding of void imaging. Here, we employ a correlative APT and STEM approach to investigate the APT imaging process and reveal that voids can lead to either an increase or a decrease in local atomic densities in the APT reconstruction. Simulated APT experiments demonstrate the local density variations near voids are controlled by the unique ring structures as voids open and the different evaporation fields of the surrounding atoms. We provide a general approach for quantifying chemical segregations near voids within an APT dataset, in which the composition can be directly determined with a higher accuracy than STEM-based techniques.

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confidence: 99%

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

et al. 2020

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“…The microstates/configurations/local orders are essential to reveal their structure-property relationship [49,50,51,52]. Predictive models have been proposed to reveal the hydrogen trapping and bubbling in nanovoids in bodycentered-cubic (BCC) metals, which integrate the multiscale calculations including DFT calculations, classical MD simulations, and kinetic Monte Carlo simulations [53]. The microstates/clusters dominated shear bands or serrations of high-entropy alloys and metallic glasses during deformation are reported [51,54].…”

Section: Electrons To Phases and Properties: Key Roles Of Microstatesmentioning

confidence: 99%

“…10(c). Therefore, with electronic and atomic structures, the mechanisms and models of hydrogen-induced damage in structural metal materials can be revealed clearly [53,61,142,143,144]. Recently, first-principles modeling of anisotropic anodic dissolution of metals and alloys in corrosive environments reveals a formula to specify the relationship between the electrode potential and the current density by considering the basic parameters of surface energy density and work function, providing a promising perspective for designing better corrosion-resistant alloys [144].…”

Section: Al Alloysmentioning

confidence: 99%

A brief review of data-driven ICME for intelligently discovering advanced structural metal materials: Insight into atomic and electronic building blocks

et al. 2020

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“…The coupled system of CH (Equation (7)) and elasticity equations (Equation (10)) can be solved to obtain the evolution of the nanovoid concentration and, consequently, the nanovoid morphology. The growth and propagation of a nanovoid can be suppressed due to various reasons, such as change in temperature, external mechanical loading and internal stresses, caused by other defects [99–102] due to which the nanovoid is finally stopped with a certain shape and a certain size. Since we are interested in studying the interaction of a pre-existing nanovoid with the A – M transformation, a circular nanovoid with a desirable size is here generated by manually stopping the coupled CH–elasticity solution contingent upon the creation of a complete nanovoid surface with the concentration varying from c = 0 to c = 1 .…”

Section: Phase Field Modelmentioning

confidence: 99%

The effect of a pre-existing nanovoid on martensite formation and interface propagation: a phase field study

Javanbakht

Ghaedi

Barchiesi

et al. 2020

Mathematics and Mechanics of Solids

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In the present work, the effect of a pre-existing nanovoid on martensitic phase transformation (PT) is investigated using the phase field approach. The nanovoid is created as a solution of the coupled Cahn–Hilliard and elasticity equations. The coupled Ginzburg–Landau and elasticity equations are solved to capture the martensitic nanostructure. The above systems of equations are solved using the finite element method and COMSOL code. The austenite ( A)–martensite ( M) interface propagation is investigated without the nanovoid and with it for different nanovoid misfit strains and different temperatures. With the nanovoid, the evolution of the moving interface is changed even before it reaches the nanovoid surface due to the nanovoid stress concentration. It is also found that for small misfit strains, pre-transformation occurs near the nanovoid. For larger misfit strains, martensite nucleates and grows near the nanovoid surface and coalesces with the moving interface. The nanovoid shows a promotive effect on the PT with an increase in the rate of transformation, which is discussed based on the transformation work distribution. The effect of the nanovoid is more pronounced on a curved interface. The nanovoid-induced martensitic growth is mainly dependent on the transformation strain tensor. Examples for different transformation strains are presented where a stable non-complete transformed sample with no void becomes unstable in the presence of the nanovoid. The presented model and results will help to develop an interaction model between nanovoids and multiphase structures at the nanoscale.

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Predictive model of hydrogen trapping and bubbling in nanovoids in bcc metals

Cited by 94 publications

References 61 publications

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

A brief review of data-driven ICME for intelligently discovering advanced structural metal materials: Insight into atomic and electronic building blocks

The effect of a pre-existing nanovoid on martensite formation and interface propagation: a phase field study

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