Topological quantum catalyst: Dirac nodal line states and a potential electrocatalyst of hydrogen evolution in the TiSi family

Topological nodal line (DNL) semimetals, a closed loop of the inverted bands in its bulk phases, result in the almost flat drumhead-like non-trivial surface states (DNSSs) with an unusually high electronic density near the Fermi level. High catalytic active sites generally associated with high elect...

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Bibliographic Details
Published inScience China materials Vol. 61; no. 1; pp. 23 - 29
Main Authors Li, Jiangxu, Ma, Hui, Xie, Qing, Feng, Shaobo, Ullah, Sami, Li, Ronghan, Dong, Junhua, Li, Dianzhong, Li, Yiyi, Chen, Xing-Qiu
Format Journal Article
LanguageEnglish
Published Beijing Science China Press 01.01.2018
Springer Nature B.V
Subjects
Carrier mobility
Catalysis
Catalysts
Chemical reactions
Chemistry and Materials Science
Chemistry/Food Science
Concept
Current carriers
Fermi level
First principles
Free energy
Hydrogen
Hydrogen evolution reactions
Hydrogen production
Levels
Materials Science
Metalloids
Metals
Platinum
topological Dirac nodal line
hydrogen evolution
semimetals
catalyst
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Summary:Topological nodal line (DNL) semimetals, a closed loop of the inverted bands in its bulk phases, result in the almost flat drumhead-like non-trivial surface states (DNSSs) with an unusually high electronic density near the Fermi level. High catalytic active sites generally associated with high electronic densities around the Fermi level, high carrier mobility and a close-to-zero free energy of the adsorbed state of hydrogen (Δ G H* ≈0) are prerequisite to design alternative of precious platinum for catalyzing electrochemical hydrogen production from water. By combining these two aspects, it is natural to consider if the DNLs are a good candidate for the hydrogen evolution reaction (HER) or not because its DNSSs provide a robust platform to activate chemical reactions. Here, through first-principles calculations we reported a new DNL TiSi-type family, exhibiting a closed Dirac nodal line due to the linear band crossings in k y =0 plane. The hydrogen adsorbed state on the surface yields Δ G H* to be almost zero and the topological charge carries participate in HER. The results highlight a new routine to design topological quantum catalyst utilizing the topological DNL-induced surface bands as active sites, rather than edge sites-, vacancy-, dopant-, strain-, or heterostructure-created active sites.
ISSN:2095-8226
2199-4501
DOI:10.1007/s40843-017-9178-4