Catalytic effect of near-surface alloying on hydrogen interaction on the aluminum surface

Wang, Yan; Zhang, Feng; Stumpf, R.; Lin, Pei; Chou, M. Y.

doi:10.1103/physrevb.83.195419

Cited by 20 publications

(28 citation statements)

References 35 publications

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“…8(c), while the Ti species are always detected from the EDS spectra of three samples (not shown here). So we believe that nanocrystalline TiO 2 and/or amorphous phase TieAl clusters, as the active species for NaAlH 4 , remain at the subsurface sites of the surface due to binding between Ti and Al near the Al surface, reducing the dissociation energy barrier of H 2 , which is agreement with the theory calculation results [33].…”

Section: 3supporting

confidence: 74%

Improvement of the hydrogen storage kinetics of NaAlH4 with nanocrystalline titanium dioxide loaded carbon spheres (Ti-CSs) by melt infiltration

Xiong

Yan

et al. 2012

International Journal of Hydrogen Energy

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Section: 3supporting

confidence: 74%

Improvement of the hydrogen storage kinetics of NaAlH4 with nanocrystalline titanium dioxide loaded carbon spheres (Ti-CSs) by melt infiltration

Xiong

Yan

et al. 2012

International Journal of Hydrogen Energy

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“…Many processes could impair the kinetic rates, such as nucleation, defect diffusion, and H 2 dissociation and diffusion at surfaces. Previous theoretical studies demonstrated that computational methods can be applied in the study of kinetic process for various hydrogen storage systems [26][27][28][29][30][31][32][33][34][35][36]), and some systems (such as AlH 3 and MgH 2 ) were reported to have undesired H 2 dissociation barriers which may hinder the reaction process [26][27][28][29][37][38][39]. Thus, as an initial stage to examine the kinetic process for MgB 2 hydrogenation and find out the possible rate limiting processes, we studied hydrogen dissociation and diffusion on MgB 2 surface in this work (and hydrogen diffusion in bulk MgB 2 in a separate paper [40]).…”

mentioning

confidence: 99%

Thermodynamic stability of transition metals on the Mg-terminatedMgB2(0001) surface and their effects on hydrogen dissociation and diffusion

et al. 2015

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The hydrogenation of MgB 2 is a critical step in the reversibility of several well-known hydrogen storage reactions. Of the many processes that must occur during rehydrogenation, at least two of them take place near the surface: the dissociation of H 2 molecules and the subsequent diffusion of atomic hydrogen. Using first-principles calculations, we determine the energetic barriers for these processes on the ideal Mg-terminated MgB 2 (0001) surface, as well as on surfaces containing transition metal dopants (Sc -Zn, Y -Cd, Pt, and Au). The calculated dissociation barrier for H 2 on the clean surface is 0.89 eV, and the surface diffusion barrier is 0.17 eV. However, we find examples of dopants that significantly decrease the activation barrier for the dissociation of H 2 . Our calculations suggest that Ni, Cu, and Pd are good catalytic candidates for the surface processes involved in MgB 2 rehydrogenation.

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“…Wang et al remind us, in favor of this role of subsurface Ti, that metallic aluminum does not absorb diatomic hydrogen from the gas phase by itself. Meanwhile, atomic hydrogen strongly reacts with aluminum surfaces to form alanes [142]. Thus, subsurface Ti would promote H 2 dissociation and enhance H mobility and adsorption [142].…”

Section: The “Single Metal” Alanatesmentioning

confidence: 99%

“…Meanwhile, atomic hydrogen strongly reacts with aluminum surfaces to form alanes [142]. Thus, subsurface Ti would promote H 2 dissociation and enhance H mobility and adsorption [142]. These effects constitute essentially the “hydrogen pump” action mechanism that was proposed for Ti [134].…”

Section: The “Single Metal” Alanatesmentioning

confidence: 99%

Alanates, a Comprehensive Review

2019

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Hydrogen storage is widely recognized as one of the biggest not solved problem within hydrogen technologies. The slow development of the materials and systems for hydrogen storage has resulted in a slow spread of hydrogen applications. There are many families of materials that can store hydrogen; among them, the alanate family can be of interest. Basic research papers and reviews have been focused on alanates of group 1 and 2. However, there are many alanates of transition metals, main group, and lanthanides that deserve attention in a review. This work is a comprehensive compilation of all known alanates. The approaches towards tuning the kinetics and thermodynamics of alanates are also covered in this review. These approaches are the formation of reactive composites, double cation alanates, or anion substitution. The crystallographic and X-ray diffraction characteristics of each alanate are presented along with this review. In the final sections, a discussion of the infrared, Raman, and thermodynamics was included.

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Catalytic effect of near-surface alloying on hydrogen interaction on the aluminum surface

Cited by 20 publications

References 35 publications

Improvement of the hydrogen storage kinetics of NaAlH4 with nanocrystalline titanium dioxide loaded carbon spheres (Ti-CSs) by melt infiltration

Improvement of the hydrogen storage kinetics of NaAlH4 with nanocrystalline titanium dioxide loaded carbon spheres (Ti-CSs) by melt infiltration

Thermodynamic stability of transition metals on the Mg-terminatedMgB2(0001) surface and their effects on hydrogen dissociation and diffusion

Alanates, a Comprehensive Review

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