An Atomic-Scale View at γ’-Fe4N as Hydrogen Barrier Material

Aleksander  Albrecht; Sang Yoon Song; Su-Hyun  Yoo; Chang-Gi  Lee; Mathias  Krämer; Y. Ma; Seok Su Sohn; Yonghyuk  Lee; Se-Ho Kim; null More Authors

doi:10.1002/admi.202500207

An Atomic-Scale View at γ’-Fe4N as Hydrogen Barrier Material

Aleksander Albrecht, Sang Yoon Song, Su-Hyun Yoo, Chang-Gi Lee, Mathias Krämer, Y. Ma, Seok Su Sohn^*, Yonghyuk Lee^*, Se-Ho Kim^*, More Authors

^*Corresponding author for this work

Team Maria Santofimia Navarro

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Hydrogen, while a promising sustainable energy carrier, presents challenges such as the embrittlement of materials due to its ability to penetrate and weaken their crystal structures. Here γ’-Fe4N nitride layers, formed on iron through a cost-effective gas nitriding, are investigated as an effective hydrogen permeation barrier. The relatively short process carried out at 570 °C consisted of pre-nitriding in an atmosphere with higher nitriding potential, followed by treatment in a nitriding potential of 0.0016 Pa−1/2 to obtain a pure γ’ layer. A combination of screening methods, including atom probe tomography, density functional theory calculations, and hydrogen permeation analysis, revealed that the nitride layer reduces hydrogen diffusion (steady-state hydrogen flux 3.21 x 10−8 mol/m2·s) by a factor of 20 compared to pure iron, at room temperature. This reduction is achieved by creating energetically unfavorable states due to stronger hydrogen-binding at the surface and high energy barriers for diffusion. The findings demonstrate the potential of γ’-Fe4N as a cost-efficient and easy-to-process solution to protect metallic materials exposed to hydrogen at low temperatures, with great advantages for large-scale applications.

Original language	English
Article number	2500207
Number of pages	10
Journal	Advanced Materials Interfaces
Volume	12
Issue number	13
DOIs	https://doi.org/10.1002/admi.202500207
Publication status	Published - 2025

Keywords

electrolytic hydrogen charging
FeN
hydrogen diffusion barrier
hydrogen imaging
nitriding steel

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10.1002/admi.202500207

Adv Materials Inter - 2025 - Albrecht - An Atomic‐Scale View at ‐Fe4N as Hydrogen Barrier MaterialFinal published version, 2 MBLicence: CC BY

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abstract = "Hydrogen, while a promising sustainable energy carrier, presents challenges such as the embrittlement of materials due to its ability to penetrate and weaken their crystal structures. Here γ{\textquoteright}-Fe4N nitride layers, formed on iron through a cost-effective gas nitriding, are investigated as an effective hydrogen permeation barrier. The relatively short process carried out at 570 °C consisted of pre-nitriding in an atmosphere with higher nitriding potential, followed by treatment in a nitriding potential of 0.0016 Pa−1/2 to obtain a pure γ{\textquoteright} layer. A combination of screening methods, including atom probe tomography, density functional theory calculations, and hydrogen permeation analysis, revealed that the nitride layer reduces hydrogen diffusion (steady-state hydrogen flux 3.21 x 10−8 mol/m2·s) by a factor of 20 compared to pure iron, at room temperature. This reduction is achieved by creating energetically unfavorable states due to stronger hydrogen-binding at the surface and high energy barriers for diffusion. The findings demonstrate the potential of γ{\textquoteright}-Fe4N as a cost-efficient and easy-to-process solution to protect metallic materials exposed to hydrogen at low temperatures, with great advantages for large-scale applications.",

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AU - Yoo, Su-Hyun

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AU - Krämer, Mathias

AU - Ma, Y.

AU - Sohn, Seok Su

AU - Lee, Yonghyuk

AU - Kim, Se-Ho

AU - More Authors, null

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N2 - Hydrogen, while a promising sustainable energy carrier, presents challenges such as the embrittlement of materials due to its ability to penetrate and weaken their crystal structures. Here γ’-Fe4N nitride layers, formed on iron through a cost-effective gas nitriding, are investigated as an effective hydrogen permeation barrier. The relatively short process carried out at 570 °C consisted of pre-nitriding in an atmosphere with higher nitriding potential, followed by treatment in a nitriding potential of 0.0016 Pa−1/2 to obtain a pure γ’ layer. A combination of screening methods, including atom probe tomography, density functional theory calculations, and hydrogen permeation analysis, revealed that the nitride layer reduces hydrogen diffusion (steady-state hydrogen flux 3.21 x 10−8 mol/m2·s) by a factor of 20 compared to pure iron, at room temperature. This reduction is achieved by creating energetically unfavorable states due to stronger hydrogen-binding at the surface and high energy barriers for diffusion. The findings demonstrate the potential of γ’-Fe4N as a cost-efficient and easy-to-process solution to protect metallic materials exposed to hydrogen at low temperatures, with great advantages for large-scale applications.

AB - Hydrogen, while a promising sustainable energy carrier, presents challenges such as the embrittlement of materials due to its ability to penetrate and weaken their crystal structures. Here γ’-Fe4N nitride layers, formed on iron through a cost-effective gas nitriding, are investigated as an effective hydrogen permeation barrier. The relatively short process carried out at 570 °C consisted of pre-nitriding in an atmosphere with higher nitriding potential, followed by treatment in a nitriding potential of 0.0016 Pa−1/2 to obtain a pure γ’ layer. A combination of screening methods, including atom probe tomography, density functional theory calculations, and hydrogen permeation analysis, revealed that the nitride layer reduces hydrogen diffusion (steady-state hydrogen flux 3.21 x 10−8 mol/m2·s) by a factor of 20 compared to pure iron, at room temperature. This reduction is achieved by creating energetically unfavorable states due to stronger hydrogen-binding at the surface and high energy barriers for diffusion. The findings demonstrate the potential of γ’-Fe4N as a cost-efficient and easy-to-process solution to protect metallic materials exposed to hydrogen at low temperatures, with great advantages for large-scale applications.

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An Atomic-Scale View at γ’-Fe4N as Hydrogen Barrier Material

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