Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation

Hussein, Abdelrahman; Kim, Byungki; Depover, Tom; Verbeken, Kim

Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation

Abdelrahman Hussein (UGent) , Byungki Kim, Tom Depover (UGent) and Kim Verbeken (UGent)

(2024) INTERNATIONAL JOURNAL OF HYDROGEN ENERGY. 55. p.1445-1455

Author

Abdelrahman Hussein (UGent) , Byungki Kim, Tom Depover (UGent) and Kim Verbeken (UGent)

Organization

Department of Materials, Textiles and Chemical Engineering

Project

A computational framework for quantifying hydrogen embrittlement in steels

Abstract

Hydrogen grain boundary (GB) trapping is widely accepted as the main cause for hydrogen induced intergranular failure. Several studies were conducted to unveil the role of GBs on hydrogen transport; however, a clear understanding is yet to be attained. This is due to the limitations of the state-of-the-art experimental procedures for such highly kinetic processes. In this study, we aim at providing a deeper understanding of hydrogen-GB interactions using full-field representative volume element (RVE). The phase-field method is chosen for generating RVEs, since it is an appropriate numerical tool to represent GBs. A novel fully-kinetic formulation for hydrogen diffusion and GB trapping is presented, which is compatible with the phase-field based RVEs. GB diffusivity (Dgb) and trap-binding energy (Egb) were used as parameters to understand the interactions between diffusion and GB trapping. Uptake and permeation simulations were performed with constant and gradient occupancy boundary conditions respectively. In both cases, increasing Egb , increased the hydrogen GB occupancy. The permeation simulations showed that the hydrogen flux along the GBs increased with increasing both, Dgb and, surprisingly, Egb. Since trapping increases the hydrogen occupancy along GBs, it also increases the occupancy gradients, resulting in a higher flux. This led to the conclusion that, in the case of an external occupancy gradient, GB trapping and diffusion cooperate, rather than compete, to increase the hydrogen flux. On the other hand, the decisive factor for the retention of hydrogen at the GBs in permeation simulations was Dgb rather than Egb.

Keywords

Energy Engineering and Power Technology, Condensed Matter Physics, Fuel Technology, Renewable Energy, Sustainability and the Environment, Hydrogen embrittlement, Permeation simulation, Representative volume, element, Phase-field, Triple junctions, SOLUTE DRAG, SEGREGATION, PERMEATION, COEFFICIENT, IRON, PARAMETERS, ALLOYS, TRAPS, SIZE

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01HR7CXD9G4WNHMT9YRNEEX6XV

MLA: Hussein, Abdelrahman, et al. “Modeling the Effect of Grain Boundary Diffusivity and Trapping on Hydrogen Transport Using a Phase-Field Compatible Formulation.” INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, vol. 55, 2024, pp. 1445–55, doi:10.1016/j.ijhydene.2023.11.270.
APA: Hussein, A., Kim, B., Depover, T., & Verbeken, K. (2024). Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 55, 1445–1455. https://doi.org/10.1016/j.ijhydene.2023.11.270
Chicago author-date: Hussein, Abdelrahman, Byungki Kim, Tom Depover, and Kim Verbeken. 2024. “Modeling the Effect of Grain Boundary Diffusivity and Trapping on Hydrogen Transport Using a Phase-Field Compatible Formulation.” INTERNATIONAL JOURNAL OF HYDROGEN ENERGY 55: 1445–55. https://doi.org/10.1016/j.ijhydene.2023.11.270.
Chicago author-date (all authors): Hussein, Abdelrahman, Byungki Kim, Tom Depover, and Kim Verbeken. 2024. “Modeling the Effect of Grain Boundary Diffusivity and Trapping on Hydrogen Transport Using a Phase-Field Compatible Formulation.” INTERNATIONAL JOURNAL OF HYDROGEN ENERGY 55: 1445–1455. doi:10.1016/j.ijhydene.2023.11.270.
Vancouver: 1.
Hussein A, Kim B, Depover T, Verbeken K. Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY. 2024;55:1445–55.
IEEE: [1]
A. Hussein, B. Kim, T. Depover, and K. Verbeken, “Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation,” INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, vol. 55, pp. 1445–1455, 2024.

@article{01HR7CXD9G4WNHMT9YRNEEX6XV,
  abstract     = {{Hydrogen grain boundary (GB) trapping is widely accepted as the main cause for hydrogen induced intergranular failure. Several studies were conducted to unveil the role of GBs on hydrogen transport; however, a clear understanding is yet to be attained. This is due to the limitations of the state-of-the-art experimental procedures for such highly kinetic processes. In this study, we aim at providing a deeper understanding of hydrogen-GB interactions using full-field representative volume element (RVE). The phase-field method is chosen for generating RVEs, since it is an appropriate numerical tool to represent GBs. A novel fully-kinetic formulation for hydrogen diffusion and GB trapping is presented, which is compatible with the phase-field based RVEs. GB diffusivity (Dgb) and trap-binding energy (Egb) were used as parameters to understand the interactions between diffusion and GB trapping. Uptake and permeation simulations were performed with constant and gradient occupancy boundary conditions respectively. In both cases, increasing Egb , increased the hydrogen GB occupancy. The permeation simulations showed that the hydrogen flux along the GBs increased with increasing both, Dgb and, surprisingly, Egb. Since trapping increases the hydrogen occupancy along GBs, it also increases the occupancy gradients, resulting in a higher flux. This led to the conclusion that, in the case of an external occupancy gradient, GB trapping and diffusion cooperate, rather than compete, to increase the hydrogen flux. On the other hand, the decisive factor for the retention of hydrogen at the GBs in permeation simulations was Dgb rather than Egb.}},
  author       = {{Hussein, Abdelrahman and Kim, Byungki and Depover, Tom and Verbeken, Kim}},
  issn         = {{0360-3199}},
  journal      = {{INTERNATIONAL JOURNAL OF HYDROGEN ENERGY}},
  keywords     = {{Energy Engineering and Power Technology,Condensed Matter Physics,Fuel Technology,Renewable Energy, Sustainability and the Environment,Hydrogen embrittlement,Permeation simulation,Representative volume,element,Phase-field,Triple junctions,SOLUTE DRAG,SEGREGATION,PERMEATION,COEFFICIENT,IRON,PARAMETERS,ALLOYS,TRAPS,SIZE}},
  language     = {{eng}},
  pages        = {{1445--1455}},
  title        = {{Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation}},
  url          = {{http://doi.org/10.1016/j.ijhydene.2023.11.270}},
  volume       = {{55}},
  year         = {{2024}},
}

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Modeling the effect of grain boundary diffusivity and trapping on hydrogen transport using a phase-field compatible formulation

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