Chemical Synthesis and Oxide Dispersion Properties of Strengthened Tungsten via Spark Plasma Sintering

Ding, Xiao-Yu; Luo, Laima; Chen, Hongyu; Zhu, Xiaohua; Zan, Xiang; Cheng, Jigui; Wu, Yucheng

doi:10.3390/ma9110879

Cited by 11 publications

(1 citation statement)

References 22 publications

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“…Y 2 O 3 doping affords fine grains while expanding the grain boundary [19,20,25]. However, since the interactions at the W/Y 2 O 3 interface are weaker than those at the W/W interface, the W/Y 2 O 3 interface accumulates strain easily, resulting in cracks [28][29][30]. Therefore, investigation of W-Y 2 O 3 interface structures is an important research direction.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Wen¹,

Zhang²,

Deng³

et al. 2022

Nucl. Fusion

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Here, first-principles calculations were employed to study the properties of the W/Y2O3 interface and its effect on H dissolution and migration. Two W/Y2O3 interface structures were selected to investigate the influence of terminal structures and stacking sequences on the interface properties. The Y4O6–W (bridge) and O–W type A terminal interface exhibited the lowest interface energy at the W (110)/Y2O3 (222) interface with the orientation of W (1-10) ( 2 2 × 5 )/Y2O3 (2-1-1) ( 3 / 2 × 2 ) and at the W (200)/Y2O3 (400) interface with the orientation of W (001) (3 × 3)/Y2O3 (001) (1 × 1). The work of adhesion of the O–W type terminal interface is larger than those of the Y–W type and Y n O m –W terminal interfaces, indicating that the O–W type A terminal interface has the most stable structure. Atomic-bonding analysis confirmed that the W–O bond plays an essential role in stabilizing the interface structure, and the stability improves as the density of the W–O bonds at the interface increases. These conclusions are further verified by charge-density difference calculations, which revealed that strong ionic bonds are formed between the W and O atoms at the W/Y2O3 interface. With regard to the H behavior at the W (200)/Y2O3 (400) interface, the segregation energy confirmed that the interface plays an important role in the segregation of H. The migration energy barrier of interstitial H along the interface is greater than that in the bulk. This means that the interface retains a significant number of injected H atoms, leading to an increase in the local concentration of H atoms at the interface. These results provide theoretical insights into the profound understanding of the interface properties and its effect on H behavior in Y2O3-dispersion-strengthened W.

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Section: Introductionmentioning

confidence: 99%

Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Wen¹,

Zhang²,

Deng³

et al. 2022

Nucl. Fusion

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Recent Advances on Interface Design and Preparation of Advanced Tungsten Materials for Plasma Facing Materials

Zhang

et al. 2020

J Fusion Energ

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Properties and microstructure of oxide dispersion strengthened tungsten alloy prepared by liquid-phase method: a review

Xiao

et al. 2022

Tungsten

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Chemical Synthesis and Oxide Dispersion Properties of Strengthened Tungsten via Spark Plasma Sintering

Cited by 11 publications

References 22 publications

Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Recent Advances on Interface Design and Preparation of Advanced Tungsten Materials for Plasma Facing Materials

Properties and microstructure of oxide dispersion strengthened tungsten alloy prepared by liquid-phase method: a review

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Chemical Synthesis and Oxide Dispersion Properties of Strengthened Tungsten via Spark Plasma Sintering

Cited by 11 publications

References 22 publications

Investigation of the W/Y2O3 heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Investigation of the W/Y2O3 heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Recent Advances on Interface Design and Preparation of Advanced Tungsten Materials for Plasma Facing Materials

Properties and microstructure of oxide dispersion strengthened tungsten alloy prepared by liquid-phase method: a review

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Product

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Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations

Investigation of the W/Y₂O₃ heterogeneous interface properties and its effect on hydrogen behavior using first-principles calculations