Chenqiang Hua scite author profile

SnSe is a promising thermoelectric material with record-breaking figure of merit. However, to date a comprehensive understanding of the electronic structure and most critically, the self-hole-doping mechanism in SnSe is still absent. Here we report the highly anisotropic electronic structure of SnSe investigated by angle-resolved photoemission spectroscopy, in which a unique pudding-mould-shaped valence band with quasi-linear energy dispersion is revealed. We prove that p-type doping in SnSe is extrinsically controlled by local phase segregation of SnSe2 microdomains via interfacial charge transferring. The multivalley nature of the pudding-mould band is manifested in quantum transport by crystallographic axis-dependent weak localisation and exotic non-saturating negative magnetoresistance. Strikingly, quantum oscillations also reveal 3D Fermi surface with unusual interlayer coupling strength in p-SnSe, in which individual monolayers are interwoven by peculiar point dislocation defects. Our results suggest that defect engineering may provide versatile routes in improving the thermoelectric performance of the SnSe family.

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Rashba valleys and quantum Hall states in few-layer black arsenic

Sheng

Hua

Cheng

et al. 2021

Nature

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Tunable Topological Energy Bands in 2D Dialkali‐Metal Monoxides

Hua

et al. 2020

Advanced Science

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2D materials with nontrivial energy bands are highly desirable for exploring various topological phases of matter, as low dimensionality opens unprecedented opportunities for manipulating the quantum states. Here, it is reported that monolayer (ML) dialkali‐metal monoxides, in the well‐known 2H‐MoS2 type lattice, host multiple symmetry‐protected topological phases with emergent fermions, which can be effectively tuned by strain engineering. Based on first‐principles calculations, it is found that in the equilibrium state, ML Na2O is a 2D double Weyl semimetal, while ML K2O is a 2D pseudospin‐1 metal. These exotic topological states exhibit a range of fascinating effects, including universal optical absorbance, super Klein tunneling, and super collimation effect. By introducing biaxial or uniaxial strain, a series of quantum phase transitions between 2D double Weyl semimetal, 2D Dirac semimetal, 2D pseudospin‐1 metal, and semiconductor phases can be realized. The results suggest monolayer dialkali‐metal monoxides as a promising platform to explore fascinating physical phenomena associated with novel 2D emergent fermions.

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Topology and ferroelectricity in group-V monolayers*

Rehman

Hua

2020

Chinese Phys. B

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The group-V monolayers (MLs) have been studied intensively after the experimental fabrication of two-dimensional (2D) graphene and black phosphorus. The observation of novel quantum phenomena, such as quantum spin Hall effect and ferroelectricity in group-V elemental layers, has attracted tremendous attention because of the novel physics and promising applications for nanoelectronics in the 2D limit. In this review, we comprehensively review recent research progress in engineering of topology and ferroelectricity, and several effective methods to control the quantum phase transition are discussed. We then introduce the coupling between topological orders and ferroelectric orders. The research directions and outlooks are discussed at the end of the perspective. It is expected that the comprehensive overview of topology and ferroelectricity in 2D group-V materials can provide guidelines for researchers in the area and inspire further explorations of interplay between multiple quantum phenomena in low-dimensional systems.

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Doping-Induced Superconductivity in the Topological Semimetal Mo₅Si₃

Hua

Liu

et al. 2020

Chem. Mater.

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Chemical doping of topological materials may provide a possible route for realizing topological superconductivity. However, all such cases known so far are based on chalcogenides. Here we report the discovery of superconductivity induced by Re doping in the topological semimetal Mo 5 Si 3 with a tetragonal structure. Partial substitution of Re for Mo in Mo 5−x Re x Si 3 results in an anisotropic shrinkage of the unit cell up to the solubility limit of approximately x = 2. Over a wide doping range (0.5 ≤ x ≤ 2), these silicides are found to be weakly coupled superconductors with a fully isotropic gap. T c increases monotonically with x from 1.67 to 5.78 K, the latter of which is the highest among superconductors of the same structural type. This trend in T c correlates well with the variation of the number of valence electrons and is mainly ascribed to the enhancement of electron−phonon coupling. In addition, band structure calculations reveal that superconducting Mo 5−x Re x Si 3 exhibits nontrivial band topology characterized by Z 2 invariants (1;000) or (1;111) depending on the Re doping level. Our results suggest that transition metal silicides are a fertile ground for the exploration of candidate topological superconductors.

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Chenqiang Hua

Defects controlled hole doping and multivalley transport in SnSe single crystals

Rashba valleys and quantum Hall states in few-layer black arsenic

Tunable Topological Energy Bands in 2D Dialkali‐Metal Monoxides

Topology and ferroelectricity in group-V monolayers*

Doping-Induced Superconductivity in the Topological Semimetal Mo₅Si₃

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About

Chenqiang Hua

Defects controlled hole doping and multivalley transport in SnSe single crystals

Rashba valleys and quantum Hall states in few-layer black arsenic

Tunable Topological Energy Bands in 2D Dialkali‐Metal Monoxides

Topology and ferroelectricity in group-V monolayers*

Doping-Induced Superconductivity in the Topological Semimetal Mo5Si3

Contact Info

Product

Resources

About

Doping-Induced Superconductivity in the Topological Semimetal Mo₅Si₃