Xiaofeng Tian scite author profile

Hydrogen-induced disproportionation (HID) during the cycles of absorption and desorption leads to a serious decline in the storage capacity of the ZrCo alloy, which has been recognized as the biggest obstacle to its application. Therefore, the prerequisite of a ZrCo application is to solve its anti-disproportionation problem in the field of rapid hydrogen isotope storage. Beyond surface modification and nanoball milling, this work systematically reviews the method of element substitution, which can obviously improve the anti-disproportionation. From a micro angle, as hydrogen atoms that occupy the 8e site in the ZrCoH3 lattice are instable and are considered to be the driving force of disproportionation, researchers believe that element substitution by changing the occupation of hydrogen atoms at the 8e site can improve the anti-disproportionation of the alloy. At present, Ti/Nb substitutions for the Zr terminal among substitute elements have an excellent anti-disproportionation performance. In this work, up-to-date research studies on anti-disproportionation and its disproportionation mechanism of the ZrCo alloy are introduced by combining experiments and simulations. Moreover, the optimization of the alloy based on the occupation mechanism of 8e sites is expected to improve the anti-disproportionation of the ZrCo alloy.

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Atomistic simulation study of deformation twinning of nanocrystalline body-centered cubic Mo

Tian

et al. 2017

Materials Science and Engineering: A

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Ab Initio Molecular Dynamics Study of the Reaction of U⁺ and U²⁺ with H₂O in the Gas Phase: Direct Classical Trajectory Calculations

Niu

Tian

et al. 2013

J. Phys. Chem. A

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The gas phase reactions of U(+) and U(2+) with H2O were investigated using an ab initio molecular dynamics method. All of the information along the minimum energy path were calculated with density functional theory (DFT) and coupled cluster methods. For U(+) with H2O, the molecular dynamics simulations yield a branching ratio of 86% for the H2 elimination channel to 14% for the H atomic elimination channel in agreement with the quadruple ion trap mass spectrometry (QIT/MS) experimental ratio of 91% to 9%. In the case of U(2+) + H2O, there is a crossing of the potential energy surfaces (PES) after the first transition state. Crossing seams between the PES and possible spin inversion processes were studied by means of the intrinsic reaction coordinate (IRC) approach. For U(2+) with H2O, all trajectories are corresponds to H atom elimination channel, this is consistent with the Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) experimental results. The chemical bonding evolution along the reaction pathways was discussed by using topological methodologies of the electron localization function (ELF).

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Xiaofeng Tian

First principle study of the behavior of helium in plutonium dioxide

Adsorption of water on UO2 (111) surface: Density functional theory calculations

Research Progress on the Anti-Disproportionation of the ZrCo Alloy by Element Substitution

Atomistic simulation study of deformation twinning of nanocrystalline body-centered cubic Mo

Ab Initio Molecular Dynamics Study of the Reaction of U⁺ and U²⁺ with H₂O in the Gas Phase: Direct Classical Trajectory Calculations

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Xiaofeng Tian

First principle study of the behavior of helium in plutonium dioxide

Adsorption of water on UO2 (111) surface: Density functional theory calculations

Research Progress on the Anti-Disproportionation of the ZrCo Alloy by Element Substitution

Atomistic simulation study of deformation twinning of nanocrystalline body-centered cubic Mo

Ab Initio Molecular Dynamics Study of the Reaction of U+ and U2+ with H2O in the Gas Phase: Direct Classical Trajectory Calculations

Contact Info

Product

Resources

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Ab Initio Molecular Dynamics Study of the Reaction of U⁺ and U²⁺ with H₂O in the Gas Phase: Direct Classical Trajectory Calculations