Hydrogen Diffusion on, into and in Magnesium Probed by DFT: A Review

Shelyapina, Marina G.

doi:10.3390/hydrogen3030017

Cited by 10 publications

(3 citation statements)

References 139 publications

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“…In addition, higher water concentration may cause additional hydrogen to occupy interstitial sites, obstructing some diffusion pathways, and decelerating hydrogen diffusion, similar to the saturation effect in metal‐hydrogen systems (e.g., Shelyapina, 2022). With respect to the (Mg + 2H) Si defect, since hydrogen atoms mainly reside in interstitial sites, this can also be a potential factor affecting hydrogen diffusivity.…”

Section: Discussionmentioning

confidence: 99%

Hydrogen Diffusion in the Lower Mantle Revealed by Machine Learning Potentials

Peng,

Deng

2024

JGR Solid Earth

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Hydrogen may be incorporated into nominally anhydrous minerals including bridgmanite and post‐perovskite as defects, making the Earth's deep mantle a potentially significant water reservoir. The diffusion of hydrogen and its contribution to the electrical conductivity in the lower mantle are rarely explored and remain largely unconstrained. Here we calculate hydrogen diffusivity in hydrous bridgmanite and post‐perovskite, using molecular dynamics simulations driven by machine learning potentials of ab initio quality. Our findings reveal that hydrogen diffusivity significantly increases with increasing temperature and decreasing pressure, and is considerably sensitive to hydrogen incorporation mechanism. Among the four defect mechanisms examined, (Mg + 2H)Si and (Al + H)Si show similar patterns and yield the highest hydrogen diffusivity. Hydrogen diffusion is generally faster in post‐perovskite than in bridgmanite, and these two phases exhibit distinct diffusion anisotropies. Overall, hydrogen diffusion is slow on geological time scales and may result in heterogeneous water distribution in the lower mantle. Additionally, the proton conductivity of bridgmanite for (Mg + 2H)Si and (Al + H)Si defects aligns with the same order of magnitude of lower mantle conductivity, suggesting that the water distribution in the lower mantle may be inferred by examining the heterogeneity of electrical conductivity.

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Section: Discussionmentioning

confidence: 99%

Hydrogen Diffusion in the Lower Mantle Revealed by Machine Learning Potentials

Peng,

Deng

2024

JGR Solid Earth

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Section: Introductionmentioning

confidence: 99%

“…It can be believed that these transformations on hydrogenation can be affected by both external and internal factors and thereby influence the nucleation and growth of the β-MgH2. Unfortunately, experimentally only the initial (α-phase) and final states (β-MgH2) can be caught, making the internal fcc structure of MgHx impossible to survey [42]. Many published articles [44][45][46][47][48][49][50] focused on the introduction of kinetic models used to fit experimental hydrogen absorption and desorption data of Mg rather than the scope of application of kinetic models according to kinetic measurement methods.…”

Section: Introductionmentioning

confidence: 99%

Experimentally Observed Nucleation and Growth Behavior of Mg/MgH2 during De/Hydrogenation of MgH2/Mg: A Review

2022

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With the increasing energy crisis and environmental problems, there is an urgent need to seek an efficient renewable energy source, and hydrogen energy is considered one of the most promising energy carriers. Magnesium is considered a promising hydrogen storage material due to its high hydrogen storage density, abundant resources, and low cost. However, sluggish kinetic performance is one of the bottlenecks hindering its practical application. The kinetic process of hydrogenation/dehydrogenation can be influenced by both external and internal factors, including temperature, pressure, elementary composition, particle size, particle surface states, irregularities in particle structure, and hydrogen diffusion coefficient. The kinetic performance of the MgH2/Mg system can be effectively improved by more active sites and nucleation centers for hydrogen absorption and desorption. Herein, we briefly review and discuss the experimentally observed nucleation and growth behavior of Mg/MgH2 during de/hydrogenation of MgH2/Mg. In particular, the nucleation and growth behavior of MgH2 during the hydrogenation of Mg is discussed from the aspect of temperature and hydrogen pressure.

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