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36 results on '"Ouyang, C Y"'

1. First-principles study of the stability of free-standing germanene in oxygen

Author

Liu, G., Liu, S. B., Xu, B., Ouyang, C. Y., Song, H. Y., and Li, X. L.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The O2 dissociation and O atoms adsorption on free-standing germanene are studied by using first-principles calculations in this letter. Compared with the spontaneous dissociation of oxygen molecule on free-standing silicene in air, germanene is more stable than silicene from kinetic point of view, with overcoming energy barrier of about 0.55 eV. Especially, in contrast with the unique chemical adsorption of O2-dissociation-induced O atoms on silicene, oxygen molecule can behave a correspondingly stable adsorption on germanene surface. Moreover, single O atom adsorption on germanene is also different to that on silicene, resulting in two opposite migration pathways on germanene surface. Furthermore, once the oxygen molecule dissociates into O atoms on germanene surface, the migration and desorption of O atoms are relatively difficult under room temperature due to the strong Ge-O bonds in the O-adsorbed germanene, in favor of forming germanium oxides. The results provide compelling evidence to show that free-standing gemanene is relatively stable in oxygen,which is different to silicene essentially.

Published
2014
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2. Is silicene stable in air? -- First principles study of oxygen adsorption and dissociation on silicene

Author

Liu, G., Lei, X. L., Wu, M. S., Xu, B., and OuYang, C. Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

The oxygen adsorption and dissociation on pristine silicene surface are studied by use of first-principles in this letter. The oxygen adsorption and dissociation on pristine silicene surface are studied by use of first-principles in this letter. It is found that the pristine silicene is not stable in air because the oxygen molecule can be easily adsorbed and dissociated into two O atoms without overcoming any energy barrier on pristine silicene surface. In addition, dissociated oxygen atoms are relatively difficult to migrate on or desorbed from pristine silicene surface, leading to poor mobility of oxygen atom. As a result, silicene would be changed into Si-O compounds in air. The work will be helpful to reveal the detail of the interaction between oxygen molecules and pristine silicene surface, especially helpful to understand the stability of silicene in air.

Published
2013

3. Molecular adsorption and strain-induced ferromagnetic semiconductor-metal transition in half-hydrogenated germanene.

Author

Wang, X., Liu, G., Liu, R. F., Luo, W. W., Sun, B. Z., Lei, X. L., Ouyang, C. Y., and Xu, B.

Subjects
TETRACYANOQUINODIMETHANE, FERROMAGNETIC materials, STRAINS & stresses (Mechanics), ELECTROPHILES, CHARGE transfer, DEFORMATIONS (Mechanics), FERMI level
Abstract

Very recently, half-hydrogenated germanene has been achieved in an experiment. In this paper, we investigate the effects of tetracyanoquinodimethane (TCNQ) molecular adsorption and strain on the electronic properties of half-hydrogenated germanene through first-principles. As an electron-acceptor molecule, TCNQ is exploited to non-covalently functionalize the half-hydrogenated germanene. However, this physical adsorption induces a ferromagnetic semiconductor–metal transition in half-hydrogenated germanene due to charge transfer from the substrate to the TCNQ molecule. More importantly, the superstructure of half-hydrogenated germanene/TCNQ is extremely sensitive to biaxial tensile strain. Under the biaxial tensile strain of 0.25%, the ferromagnetic semiconductor–metal transition induced by molecular adsorption can surprisingly be overturned. Meanwhile, a strong p-type doping is exhibited. Remarkably, it would return from a ferromagnetic semiconductor to a metal again when the biaxial tensile strain increases to 1.5%. Our analysis based on the structural and electronic properties of half-hydrogenated germanene/TCNQ indicates that such metal–semiconductor–metal transition in half-hydrogenated germanene/TCNQ under biaxial tensile strain may originate from the strong local deformation, resulting in the energy of the valence band maximum decreasing below or increasing above the Fermi level. [ABSTRACT FROM AUTHOR]

Published
2019
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4. First-principles study of the stability of free-standing germanene in oxygen atmosphere.

Author

Liu, G., Liu, S. B., Xu, B., Ouyang, C. Y., and Song, H. Y.

Subjects
STABILITY (Mechanics), GERMANIUM compounds, OXYGEN, ATMOSPHERE, SILICON compounds, DISSOCIATION (Chemistry), CHEMICAL bonds
Abstract

The O2 dissociation and O atoms adsorption on free-standing germanene are studied by using first-principles calculations in this paper. Compared with the extremely active silicene in oxygen atmosphere, germanene is found to be less active due to an energy barrier for dissociation of about 0.57 eV. Moreover, the dissociated oxygen atom follows two opposite migration pathways on the germanene surface, which is quite different from the case of silicene. Furthermore, the migration and desorption of O atoms at room temperature are relatively difficult due to the strong Ge-O bonding, resulting in the formation of germanium oxides. Our results reveal the interplay between germanene and O2 and suggest the enhanced stability of germanene in oxygen atmosphere compared with silicene. [ABSTRACT FROM AUTHOR]

Published
2015
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8. First-principles study of the oxygen adsorption and dissociation on graphene and nitrogen doped graphene for Li-air batteries.

Author

Yan, H. J., Xu, B., Shi, S. Q., and Ouyang, C. Y.

Subjects
GRAPHENE, ELECTRODES, LITHIUM cells, DISSOCIATION (Chemistry), DENSITY functionals
Abstract

Recently, Yoo and Zhou [ACS Nano 5, 3020-3026 (2011)] reported that graphene can be directly used as electrode for Li-air batteries, suggesting that graphene itself can be served as catalyst for O2 dissociation reaction. In this work, we show from density functional theory calculations that the O2 dissociation reaction energy barrier is substantially decreased on the graphene surface comparing to that of in vacuum. Furthermore, N-doping can further decrease the energy barrier from 2.39 eV (undoped case) to 1.20 eV. The O2 molecule physical adsorption, O atom chemical adsorption at the graphene, and N-doped graphene surfaces are also simulated. [ABSTRACT FROM AUTHOR]

Published
2012
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9. Understanding the effect of the layer-to-layer distance on Li-intercalated graphite.

Author

Xu, B., Wu, M. S., Liu, G., and Ouyang, C. Y.

Subjects
LITHIUM ions, GRAPHITE, ANODES, LITHIUM-ion batteries, DIFFUSION
Abstract

The lithium ion dynamics in graphite, an important anode material for lithium ion batteries, is strongly related with the layer-to-layer distance (d-spacing) and the stacking modes of graphite. We studied these relationships by first-principles calculations. It is found that a larger d-spacing results in the easier transformation of the stacking mode from A-B stacking to A-A stacking when lithium atoms are inserted. This transformation is unfavorable to the lithium diffusion because of the larger diffusion energy barrier for lithium in A-A stacking graphite compared to that in A-B one. On the other hand, as the d-spacing increases, the diffusion energy barrier for lithium in A-A stacking graphite decreases substantially, thus being favorable to the lithium diffusion. These results give a better understanding of the lithium ion dynamics in graphite, and show that it is possible to optimize the lithium ion dynamics in graphite by properly adjusting the d-spacing. [ABSTRACT FROM AUTHOR]

Published
2012
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10. Transition from Mn4+ to Mn3+ induced by surface reconstruction at λ-MnO2(001).

Author

Ouyang, C. Y., Sˇljivancˇanin, Zˇ., and Baldereschi, A.

Subjects
*MANGANESE, *SURFACE chemistry, *DENSITY functionals, *ELECTROLYSIS, *PHOTOSYNTHETIC oxygen evolution, *INTERMEDIATES (Chemistry), *CATIONS
Abstract

Structural and electronic properties of the λ-MnO2(001) surface are investigated applying density functional theory approach. The calculations show that all Mn ions at unreconstructed smooth surface preserve the +4 oxidation state observed in the bulk. Upon the λ-MnO2(001) reconstruction, one fourth of Mn ions at the surface undergo a change of the oxidation state from +4 to +3, although the reconstruction does not change the Mn coordination number with oxygen. This is accompanied with the filling of initially empty 3dz2 states localized on cations with one electron denoted by two neighboring O atoms. Although the reconstruction leads to an energy gain of 0.04 eV per surface unit cell, it is not a spontaneous process since it proceeds with an activation energy of 0.12 eV. [ABSTRACT FROM AUTHOR]

Published
2010
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11. Oxidation States of Mn Atoms at Clean and Al2O3-Covered LiMn2O4(001) Surfaces

Author

Ouyang, C. Y., Zeng, X. M., Šljivancanin, Ž., and Baldereschi, A.

Abstract

The electronic structures of bulk and (001) surfaces of λ-MnO2and LiMn2O4have been studied with density functional theory. In λ-MnO2, the Mn oxidation state is +4 both in the bulk and at the (001) surface. In LiMn2O4, however, Mn atoms exhibit mixed Mn3+/Mn4+oxidation states in the bulk, while only Mn3+at the (001) surface, due to lower coordination with O atoms. The technically undesired Mn3+ions form at LixMn2O4(001) even for very small Li concentrations. Upon covering the LiMn2O4(001) surface with Al2O3, the oxidation state of surface Mn atoms changes from +3 to +4, which explains the improved performance of coated LiMn2O4cathodes in Li-ion batteries.

Published
2024
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13. Tuning the electronic properties of germanene by molecular adsorption and under an external electric field.

Author

Luo, W. W., Wang, X., Lei, X. L., Xu, B., Ouyang, C. Y., Liu, G., and Liu, S. B.

Abstract

The effects of both molecular adsorption and external electric field on the electronic properties of germanene are investigated through first-principles calculations in this work. The molecular adsorption-induced intrinsic electric field by small molecules (SMs) breaks the symmetry of two sublattices in germanene, leading to a band gap opening from zero to 3.2 meV, even up to 81.0 meV. Under an external electric field, a wide ranging linearly tunable band gap (0–69.39 meV for the germanene/methane system and 37.66–134.17 meV for the germanene/ammonia system) can be realized, which is merely determined by the strength of the composited electric field independent of its direction. More importantly, the band gap of germanene/SMs can be closed and reopened under a critical electric field. On the other hand, the mechanism of charge transfer between germanene and SMs under an external electric field is revealed by an equivalent capacitor model to explain the tunable charge transfer. The composited field-induced charge transfer could be promoted when an external electric field and a molecular adsorption-induced internal electric field have the same direction. Otherwise, the charge transfer will be inhibited. Particularly, the tunable electronic properties of germanene are sensitive to the concentration of molecular adsorption under an electric field, representing multiple-effects that would significantly enhance the performance of germanene for electronic devices in the future. [ABSTRACT FROM AUTHOR]

Published
2018
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27. STRUCTURAL AND ELECTRONIC EVOLUTION FROM SHEET TO SILICENE.

Author

LIU, G., WU, M. S., OUYANG, C. Y., and XU, B.

Subjects
ELECTRONIC structure, DENSITY functional theory, MONOMOLECULAR films, MECHANICAL buckling, BAND gaps, ATOMS, SILICON carbide, NANOTECHNOLOGY
Abstract

The evolution of the structural and electronic properties from sheet to silicene is studied by using first-principles density functional theory. It is found that the planar configurations of the - monolayer systems are basically kept except for the increase of the buckling of the planar structure when the substitution ratio of Si increases. Band gaps of the - monolayer system decrease gradually when the substitution ratio of Si atoms ranges from 0% to 100%. The energy and type of the band gaps are closely related with the substitution ratio of Si atoms and the - order. Further analysis of density of states reveals the orbital contribution of and atoms near the Fermi level. The discussion of the electronic evolution from SiC sheet to silicene would widen the application of the - monolayer systems in the optoelectronic field in the future nanotechnology. [ABSTRACT FROM AUTHOR]

Published
2013
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28. FIRST-PRINCIPLES STUDY ON β-/BNNT CORE/SHELL NANOCABLE.

Author

ZOU, X. C., OUYANG, J., WU, M. S., LIU, G., LEI, X. L., OUYANG, C. Y., and XU, B.

Subjects
SILICON carbide, NANOWIRES, ELECTRONIC structure, BORON nitride, NANOTUBES, DENSITY functional theory, HETEROJUNCTIONS
Abstract

In this paper, we studied the structural and electronic properties of core/shell nanocables composed of cubic silicon carbide nanowires (β-) and boron nitride nanotubes (BNNT) using first-principles pseudopotential plane wave method within density functional theory. Our results show that the β-/BNNT heterojunction structures are metallic, which primarily originates from the contributions of the BNNTs and the surfaces of s. The BNNTs exhibit metallic characters after the nanowires are inserted. The transition of the BNNTs is attributed to the charge transfer between BNNTs and s. [ABSTRACT FROM AUTHOR]

Published
2013
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31. Transition from Mn4+ to Mn3+ induced by surface reconstruction at lambda-MnO2(001)

Author

Ouyang, C. Y., Sljivancanin, Z., and Baldereschi, A.

Subjects
States, Points, Systems, Spinel, Limn2O4, Spectra, Electronic-Structure
Abstract

Structural and electronic properties of the lambda-MnO2(001) surface are investigated applying density functional theory approach. The calculations show that all Mn ions at unreconstructed smooth surface preserve the +4 oxidation state observed in the bulk. Upon the lambda-MnO2(001) reconstruction, one fourth of Mn ions at the surface undergo a change of the oxidation state from +4 to +3, although the reconstruction does not change the Mn coordination number with oxygen. This is accompanied with the filling of initially empty 3d(z2) states localized on cations with one electron denoted by two neighboring O atoms. Although the reconstruction leads to an energy gain of 0.04 eV per surface unit cell, it is not a spontaneous process since it proceeds with an activation energy of 0.12 eV. (C) 2010 American Institute of Physics. [doi:10.1063/1.3509401]

32. Jahn-Teller distortion and electronic structure of LiMn2O4

Author

Ouyang, C. Y., Shi, S. Q., and Lei, M. S.

Subjects
Electronic structure, Jahn-Teller effect, GGA plus U, Initio Molecular-Dynamics, Spectra, Lithium ion battery, Absorption, Spinels, Batteries, Density-Functional Theory, Metals, Lixmn2O4, First principles calculation, Lambda-Mno2, Stability
Abstract

LiMn2O4 is one of the important cathode material for rechargeable lithium batteries. Standard ab initio studies within local density approximation (LDA) and generalized gradient approximation (GGA) are not able to reproduce the intrinsic insulating electronic structure and Jahn-Teller-type local atomic distortion of LiMn2O4. In the present work, GGA+U method is shown to be able to localize electrons to Mn 3d(z2) orbits in the majority spin channel, and open a gap of about 0.5 eV between the Mn 3d(z2) and Mn 3d(x2-y2). Results from GGA+U calculation showed that Mn ions are in the mixed valence state of Mn3+ and Mn4+. This is in good agreements with experimental observations and different to Mn3.5+ obtained from standard GGA calculations. While Jahn-Teller distortion is not observed in Mn4+O6 octahedra, it is clearly seen in Mn3+O6 octahedra, in which Mn-O bond lengths along the z-axis direction are obviously elongated. (C) 2008 Elsevier B.V. All rights reserved.

35. Is silicene stable in O2? —First-principles study of O2 dissociation and O2-dissociation–induced oxygen atoms adsorption on free-standing silicene.

Author

Liu, G., Lei, X. L., Wu, M. S., Xu, B., and Ouyang, C. Y.

Abstract

The stability of free-standing silicene in O2 is an open question. In this letter, the O2 dissociation and O2-dissociation–induced O atoms adsorption on free-standing silicene are studied by using first-principles calculations. Our results show that the O2 molecule dissociates on the free-standing silicene surface easily from both the thermodynamic and kinetic points of view, which is different from the case of graphene. The dissociation reaction is an exothermic process, and the dissociated O atoms form strong bonds with Si atoms, which lowers the energy of the system substantially. On the other hand, the dissociation reaction occurs spontaneously on the free-standing silicene without overcoming any energy barrier. Furthermore, the migration and desorption of O atoms are relatively difficult under room temperature due to the strong Si-O bonds in the O-adsorbed silicene, which is in favor of forming silicon oxides. Our results provide convictive evidence to show that free-standing silicene is unstable in O2. [ABSTRACT FROM AUTHOR]

Published
2014
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36. Polaron states and migration in F-doped Li2MnO3.

Author

Wang, Z. Q., Chen, Y. C., and Ouyang, C. Y.

Subjects
*CATHODES, *MANGANESE oxides, *LITHIUM-ion batteries, *ELECTRIC conductivity, *POLARONS, *ELECTRIC discharges
Abstract

Li2MnO3 compound is one essential component of the Li-rich solid solution cathode material (mLi2MnO3⋅nLiMO2, M=Mn, Ni, Co, etc.) for lithium ion batteries. The intrinsic insulating nature of the electronic structure determines that the electronic conductivity of the Li2MnO3 compound is low, which is unfavorable to the fast charge/discharge performance of the battery. In this paper, we demonstrate that F doping can create polaron states in the Li2MnO3 lattice from first principles calculations. The small polaron migration energy barrier in the Li2MnO3 lattice is about 0.27 eV. It is also observed that the polaron state is strongly trapped by the F atom, which decreases the efficiency of the doping enhanced electronic conductivity. [ABSTRACT FROM AUTHOR]

Published
2014
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