Ab Initio Investigations for the Role of Compositional Complexities in Affecting Hydrogen Trapping and Hydrogen Embrittlement: A Review

doi:10.1007/s40195-022-01513-4

Abstract

Abstract:

ydrogen embrittlement (HE) seriously restricts the service safety of structural metallic materials applicate in aerospace, ocean, and transportation. Recent studies aiming at increasing the HE-resistance have been focusing on trapping diffusible H atoms by inherent microstructural features in materials. Alloying-induced compositional complexities, including different types of solute atoms, lattice chemical heterogeneities, and carbide precipitates, have attracted research efforts regarding the H trapping capabilities and potential to reduce the susceptibility to HE. In this paper, we review recent progress in exploiting compositional complexities to regulate the hydrogen trapping characteristics and mechanical properties in H-containing environments. The focus is placed on results and insights from ab initio calculations based on density functional theory (DFT). Quantitative predictions of trapping parameters and atomic scale details that are hardly to be gained through traditional experimental characterizations are provided. Additionally, we overview the electronic/atomistic mechanisms of H trapping energetics in metallic materials. Finally, we propose some key challenges and prospects in simulation of defect interactions, interpretation of experimental characterizations, and developing microstructure-based H diffusion prediction models. For the applications of first principle calculations, we illustrate how the DFT data can complement experimental characterizations to guide composition and microstructure design for better HE-resistant materials.

Key words: Ab initio calculations, Hydrogen trapping, Hydrogen embrittlement, Precipitation, Composition design

Boning Zhang, Yong Mao, Zhenbao Liu, Jianxiong Liang, Jun Zhang, Maoqiu Wang, Jie Su, Kun Shen. Ab Initio Investigations for the Role of Compositional Complexities in Affecting Hydrogen Trapping and Hydrogen Embrittlement: A Review[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(7): 1159-1172.

Figures/Tables 8

Table 1 H binding energies $E_{{\text{b}}}$ at stable trapping sites relative to various point defects and complexes in BCC-Fe

Type	E_b (eV/H)	Stable H site relative to point defects	Refs
Interstitial C	0.09-0.01 (single C atom)	T-site (3.5-3.8 Å to C)	[17]
Interstitial C	0.06-0.26 (various C at.%)	Near O-site	[18]
Substitutional solutes	Y (0.25, 0.21)* Sc (0.20, 0.18)* Mg (0.15) Zr (0.13) Cd (0.13) Hf (0.11) Ti (0.08, 0.06)* Ag (0.08) La (0.08) Nb (0.07, 0.04)* Zn (0.07) Cu (0.06, 0.04)* Al (0.04) Ni (0.01) Pd (0.02) Ta (0.02) V (0.01)	The second NN T-site	[17, 19]
Substitutional solutes	Y (0.05) Sc (0.04) Zr (0.03) Hf (0.03) Ti (0.01) Cu (0.01) Nb (0.01)	The third NN T-site	[19]
Vacancy and point defect complexes	0.57 (Va)	Near O-site	[17, 21]
	0.60 (C₁Va₁)	Near O-site (displaced by 0.2 Å toward the vacancy)	[17]
	0.56-0.60 (common substitutional solute-Va complexes)	O-site (3.1 Å to the solute)	[17]
	0.49 (Y₁Va₁)	O-site (2.5 Å to the solute)	[17]
	0.47 (Y₁Va₁) 0.73 (Y₂Va₂) 0.81 (Y₂Va₄)	The 1^st NN T-site of Y atoms	[22]

Fig. 1 Effect of nanoscale chemical heterogeneities on a distribution of H solution energies in various high alloyed FCC [31], b H segregation tendency to GBs [31], c H migration energy profiles along different paths [33], d trajectories of H diffusion showing the blocking effect from high-energy positions [34], and e H-induced change of fracture free energy and unstable stacking fault energy [37]. f Ab initio-based predictions of embrittled (red) and un-embrittled (blue) domains of H concentrations and comparison with experiments [37]

Fig. 2 Interaction between GB-segregated alloying and H atoms. a Prediction chart of solute/solvent (GB/matrix) combinations that could enhance (green) or hinder (red) H diffusion compared to a homogeneous solid solution alloy [41]. b Effect of H-solute interaction on the GB segregation energy, GB strengthening energy, and the bulk partial cohesive energy [39]

Fig. 3 Ab initio calculations of the correlation between the size of TiC carbides and $E_{{\text{b}}}$ [46]. The energy profiles for a perfect coherent interface (red) and misfit dislocation core of semi-coherent interface (black), b coherent interface with a single C vacancy at the interface and within the carbide (black), connected C vacancies (dashed black), and a single C vacancy within the carbide with two occupied H atoms (dashed red), and c the (110)Fe/(001)TiC incoherent interface with (black) and without (red) C vacancies at the interface and with C vacancies within the carbide (gray). The H desorption energies at various H trapping sites obtained by d theoretical predictions and e experimental characterizations

Fig. 4 H trapping of NaCl-type MC carbides and multicomponent (M,X)C carbides. a DFT calculations of $E_{{\text{b}}}$ at different sites of coherent phase boundaries [49]. The APT analysis of deuterium-charged samples with precipitation of b VC carbides showing trapping at broad interface [60] and c (V,Mo)C carbides showing trapping inside the particles [61]

Fig. 5 Relationship between the homogeneous electron gas density and the interaction energy to H in metals [68]

Fig. 6 Ab initio investigation for the effect of stress anisotropy on H energetics in BCC metals [74]. Formation energies of H under uniaxial stress along [001] and [100] directions for a interstitial H; b planar H cluster; c di-hydrides; d the minimum formation energies from a-c; e corresponding formation volume tensor of stress-free condition; f sensitivity of formation energies to stresses

Fig. 7 Charge transfer mechanism of H trapping at phase boundaries [49]. a One H atom gains electrons from surrounding atoms; b interfacial segregated X atoms change the partial electron density distribution at region of phase boundaries; c the relationship between the charge transfer ratio R and mechanical-free binding energy for Tet-2 and C-Vac sites

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