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106 results on '"Chen, Yuan Ping"'

1. R-graphyne: a new two-dimension carbon allotrope with versatile Dirac-like point in nanoribbons

Author

Yin, Wen-Jin, Xie, Yue-E, Liu, Li-Min, Wang, Ru-Zhi, Lau, Leo, Zhong, Jian-Xin, and Chen, Yuan-Ping

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

A novel two-dimensional carbon allotrope, rectangular graphyne (R-graphyne) with tetra-rings and acetylenic linkages, is proposed by first-principles calculations. Although the bulk R-graphyne exhibits metallic property, the nanoribbons of R-graphyne show distinct electronic structures from the bulk. The most intriguing feature is that band gaps of R-graphene nanoribbons oscillate between semiconductor and metal as a function of width. Particularly, the zigzag edge nanoribbons with half-integer repeating unit cell exhibits unexpected Dirac-like fermions in the band structures. The Dirac-like fermions of the R-graphyne nanoribbons originate from the central symmetry and two sub-lattices. The extraordinary properties of R-graphene nanoribbons greatly expand our understanding on the origin of Dirac-like point. Such findings uncover a novel fascinating property of nanoribbons, which may have broad potential applications for carbon-based nano-size electronic devices.

Published
2016

2. A low-surface energy carbon allotrope: the case for bcc-C6

Author

Yin, Wen-Jin, Chen, Yuan-Ping, Xie, Yue-E., Liu, Li-Min, and Zhang, S. B.

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

Graphite may be viewed as a low-surface-energy carbon allotrope with little layer-layer interaction. Other low-surface-energy allotropes but with much stronger layer-layer interaction may also exist. Here, we report a first-principles prediction for one of the known carbon allotropes, bcc-C6 (a body centered carbon allotrope with six atoms per primitive unit) that should have exceptionally low-surface energy and little size dependence down to only a couple layer thickness. This unique property may explain the existence of the relatively-high-energy bcc-C6 during growth. The electronic properties of the bcc-C6thin layers can also be intriguing: the (111), (110), and (001) thin layers havedirect band gap, indirect band gap, and metallic character, respectively. The refrained chemical reactivity of the thin layers does not disappear after cleaving, as lithium-doped (Li-doped) 3-layers (111) has a noticeably increased binding energies of H2 molecules with a maximum storage capacity of 10.8 wt%.

Published
2016

14. Spin transistor based on T-shaped graphene junctions.

Author

Li, Hang, Chen, Yuan Ping, Xie, Yue E., and Zhong, JianXin

Subjects
*GRAPHENE, *POLYCYCLIC aromatic hydrocarbons, *GREEN'S functions, *FERROMAGNETISM, *MAGNETISM
Abstract

We propose a spin device based on a T-shaped graphene junction (TGJ) in which a ferromagnetic insulator and a metallic gate are deposited on the sidearm. Spin transport properties of the TGJ are studied by using the Green's function method. It is found that spin-polarized transport can be achieved both far away from and near the Dirac point. The spin polarization far away from the Dirac point is correlated with the quasi-bound states in the junction, while the spin polarization near the Dirac point is due to the destruction of edge states. By varying the strength of the potential, i.e., the gate voltage on the sidearm, the spin polarization can be tuned quasi-periodically from -100% to 100%. In addition, the size of the sidearm also shows obvious influence on the spin polarization of TGJ. [ABSTRACT FROM AUTHOR]

Published
2011
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15. Electron transport of folded graphene nanoribbons.

Author

Xie, Yue E., Chen, Yuan Ping, and Zhong, JianXin

Subjects
*ELECTRON transport, *NANOSTRUCTURED materials, *GRAPHENE, *DIRAC equation, *ELECTRIC conductivity
Abstract

Recently, the AA-stack bilayer graphene nanoribbon (BGN) with a closed edge is observed in experiment. This new type of GN, we called folded GN (FGN), can be formed by folding a monolayer GN (MGN). Electron transport of the folded structures with different edges is studied. The FGNs show unique transport properties different from those of MGNs and BGNs. A metallic MGN with armchair edge (MAGN) is still metallic after folding. However, a semiconducting MAGN can be either semiconducting or metallic after folding, which depends on the width of MAGN and strength of interlayer coupling in the folded structure. The energy gap decreases with the increase of the coupling strength or width. As to the MGNs with zigzag edge (MZGNs), after folding they exhibit interesting conductance characteristics. The conductance steps around the Dirac point are even multiple of G0=2e2/h, while other conductance steps are odd multiple of G0. It indicates that the electron transport around the Dirac point in zigzag-edged FGNs (FZGNs) is similar to that in zigzag-edged BGNs (BZGNs), while electron transport far from the Dirac point is similar to that in zigzag-edged MGNs (MZGNs). [ABSTRACT FROM AUTHOR]

Published
2009
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17. Characteristics of bacterial vaginosis infection in cervical lesions with high risk human papillomavirus infection

Author

Lu, Huan, Jiang, Peng-Cheng, Zhang, Xiao-Dan, Hou, Wen-Jing, Wei, Zhen-Hong, Lu, Jia-Qi, Zhang, Hao, Xu, Guang-Xu, Chen, Yuan-Ping, Ren, Yuan, Wang, Li, Zhang, Rong, and Han, Ying

Subjects
virus diseases, Original Article, female genital diseases and pregnancy complications
Abstract

High risk human papillomavirus (HPV) infection is the major cause of cervical cancer. Bacterial vaginosis (BV) is considered as the most prevalent vaginal imbalance affecting women of reproductive age. However, the relationship between HPV and BV infection is unclear. This study aimed to assess the prevalence of human papillomavirus (HPV) infection combined with bacterial vaginosis (BV) infection in Shanghai suburbs and evaluate associations between bacterial vaginosis with HPV infection, cervical intraepithelial neoplasia (CIN) and cervical cancer. Methods: From October 1, 2009 to October 31, 2013, a total number of 3502 women who visited Fengxian Hospital, Southern Medical University were enrolled in this study. All participants gave informed consent and agreed to HPV, BV, chlamydia, mycoplasma and thinprepcytologic test (TCT). In addition, all women took histopathologic examination under colposcopy. Statistical analyses were done using SPSS 17.0 for windows (IBM). In present study the overall BV-positive rate was 9.25%. The top three high risk HPV types were listed as follows (in descending order): HPV16, 52, 58. Moreover, our data showed BV infection tended to occur in the HPV positive women, HPV infection also tended to occur in the BV positive women. Most of the women who present HPV with BV infection were younger than 30 years old. We also found that CIN and cervical cancer occurred mainly in HPV/BV positive and HPV with BV positive group. BV infection and HPV infection may haveconsistency or synergies. HPV with BV infection may increase the incidence of CIN and cervical cancer.

Published
2015

19. Nonideal effects in quantum field-effect directional coupler

Author

Xie Yue-E, Yan Xiao-Hong, and Chen Yuan-Ping

Subjects
Physics, Electron transfer, Condensed matter physics, Lattice (order), General Physics and Astronomy, Power dividers and directional couplers, Rectangular potential barrier, Conductance, Electron, Quantum field theory, Quantum
Abstract

The nonideal effects in a quantum field-effect directional coupler where two quantum wires are coupled through a finite potential barrier are studied by adopting the lattice Green function method. The results show that the electron energy distribution, asymmetric geometry and finite temperature all have obvious influence on the electron transfer of the coupler. Only for the electrons with energies in a certain region, can the complete periodic transfer between two quantum wires take place. The conductance of these electrons as a function of the barrier length and potential height exhibits a fine periodic or quasi-periodic pattern. For the electrons with energies beyond the region, however, the complete periodic transfer does not hold any more since many irregular oscillations are superimposed on the conductance profile. In addition, the finite temperature and asymmetric geometry both can reduce the electron transfer efficiency.

Published
2006
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20. Electron transport across a quantum wire embedding a saw-tooth superlattice

Author

Deng Yu-Xiang, Chen Yuan-Ping, Lu Mao-Wang, and Yan Xiao-Hong

Subjects
Physics, Condensed matter physics, Quantum dot, Quantum wire, Superlattice, General Physics and Astronomy, Embedding, Field strength, Transmission coefficient, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Fermi gas, Magnetic field
Abstract

By developing the recursive Green function method, the transport properties through a quantum wire embedding a finite-length saw-tooth superlattice are studied in the presence of magnetic field. The effects of magnetic modulation and the geometric structures of the superlattice on transmission coefficient are discussed. It is shown that resonant peak splitting of this kind of structure is different from that of `magnetic' and `electric' superlattices in two-dimensional electron gas. The transmission spectrum can be tailored to match requirements through adjusting the size of saw-tooth quantum dot and field strength.

Published
2004
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29. Spin gapless armchair graphene nanoribbons under magnetic field and uniaxial strain

Author

Chen Yuan-Ping, Hou Hai-Ping, Zhong Jian-Xin, Xie Yue-E, Ge Qing-Xia, and Ouyang Tao

Subjects
Materials science, Condensed matter physics, Graphene, business.industry, General Physics and Astronomy, law.invention, Magnetic field, Semiconductor, Gapless playback, Tight binding, law, Electrical resistivity and conductivity, business, Graphene nanoribbons, Spin-½
Abstract

Using Green's function method, we investigate the spin transport properties of armchair graphene nanoribbons (AGNRs) under magnetic field and uniaxial strain. Our results show that it is very difficult to transform narrow AGNRs directly from semiconductor to spin gapless semiconductors (SGS) by applying magnetic fields. However, as a uniaxial strain is exerted on the nanoribbons, the AGNRs can transform to SGS by a small magnetic field. The combination mode between magnetic field and uniaxial strain displays a nonmonotonic arch-pattern relationship. In addition, we find that the combination mode is associated with the widths of nanoribbons, which exhibits group behaviors.

Published
2013
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32. Thermal transport of graphene nanoribbons embedding linear defects

Author

Yao Hai-Feng, Ouyang Tao, Xie Yue-E, and Chen Yuan-Ping

Subjects
Materials science, Thermal conductivity, Local density of states, Condensed matter physics, Zigzag, Phonon, Graphene, law, General Physics and Astronomy, Embedding, Transmission coefficient, Graphene nanoribbons, law.invention
Abstract

Using nonequilibrium Green's function method, the thermal transport properties of zigzag graphene nanoribbons (ZGNR) embedding a finite (semi-infinite or infinite) long linear defect are investigated in this paper. The results show that defect type and defect length have significant influence on the thermal conductance of ZGNR. When the embedded linear defects have the same lengths, thermal conductance of ZGNR embedding t5t7 defect is lower than that of ZGNR embedding Stone-Wales defect. As for the ZGNR embedding finite and the same type defects, their thermal conductance reduce with the increase of the defect length. However, as the linear defect is long enough, the thermal conductance is insensitive to the change of length. By comparing the ZGNRs embedding finite, semi-infinite and infinite long defects, we find that the thermal conductance of ZGNR embedding an infinite long defect is higher than that of ZGNR embedding a semi-infinite defect, while the thermal conductance of the latter is higher than that of ZGNR embedding a finite long defect. This is due to the fact that different structures possess different numbers of scattering interfaces in the phonon transmission direction. The more the scattering interfaces, the lower the thermal conductance is. These thermal transport phenomena are explained by analyzing transmission coefficient and local density of states. These results indicate that linear defects can tune thermal transport property of ZGNR efficiently.

Published
2013
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33. Studies on electrical properties of graphene nanoribbons with pore defects

Author

Wei Xiao-Lin, Zhong Jian-Xin, Chen Yuan-Ping, and Wang Ru-Zhi

Subjects
Materials science, Condensed matter physics, Hydrogen, Graphene, General Physics and Astronomy, Conductance, chemistry.chemical_element, law.invention, Tetragonal crystal system, Zigzag, chemistry, law, Particle, Electron scattering, Graphene nanoribbons
Abstract

In practical applications of graphene-based electronic devices, they may have some pore defects under energetic particle bombardment, or chemical corrosion, which will inevitably affect their electrical properties. These problems have recently aroused great concern and interest. In this paper, we systematically study the influence of shape (tripartite, tetragonal and hexagonal) of hole defect on the electrical property of zigzag graphene nanoribbon (ZGNR). The results show that the influence of the shape of the pore defects on the conductance and current characteristics of ZGNRs is significant, whicl may result from electron scattering for the different shapes of the poredefect boundary. In addition, due to defects in suspension adsorbed hydrogen or nitrogen atoms, caused by defects of the pore shape changes, it also affects the electrical properties of ZGNRs. This study will supply valuable theoretical guidances for graphene-based electronic device failure analysis and the design of the graphene pore structure.

Published
2013
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40. Electronic properties of disordered bilayer hexagonal boron nitride quantum films

Author

Sun Li-Zhong, Wei Xiao-Lin, Chen Yuan-Ping, Zhong Jian-Xin, Yang Kai-Ke, and Xiao Hua-Ping

Subjects
Condensed Matter::Materials Science, Materials science, Condensed matter physics, Condensed Matter::Superconductivity, Bilayer, General Physics and Astronomy, Hexagonal boron nitride, Metal–insulator transition, Condensed Matter::Disordered Systems and Neural Networks, Quantum, Electronic properties
Abstract

Based on the Anderson tight-binding model, the electronic properties of disordered bilayer hexagonal boron nitride quantum films are investigated. Our numerical results show that the electrons in a disordered bilayer hexagonal boron nitride quantum film are localized, presenting an insulating property. However, for the monolayer disordered bilayer hexagonal boron nitride quantum film, the energy spectrum has persistent mobility edges which are independent of the disorder strength. This indicates that a metal-insulator transition occurs in the monolayer disorder structure. This is similar to the case in an order-disorder separated quantum film. The results could offer useful information for understanding and manipulating the electronic properties of bilayer hexagonal boron nitride quantum films.

Published
2012
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42. Thermal transport in L-shaped graphene nano-junctions

Author

Zhong Jian-Xin, Bao Zhi-Gang, Yang Kai-Ke, Chen Yuan-Ping, and Ouyang Tao

Subjects
Thermal transport, Materials science, Graphene, law, Nano, Physics::Optics, General Physics and Astronomy, Nanotechnology, Physics::Chemical Physics, Graphene nanoribbons, law.invention, Graphene oxide paper
Abstract

By using nonequilibrium Green’s function method, the thermal transport properties of L-shaped graphene nano-junctions consisting of a semi-infinite armchair-edged nanoribbon and a semi-infinite zigzag-edged nanoribbon were studied. It is shown that the thermal conductance of the L-shaped graphene nano-junctions depends on the included angles and the widths of the graphene nanoribbons. As the angle of L-shaped graphene nano-junctions increases from 30° to 90° and further to 150°, the thermal conductance obviously increases. For the right-angle L-shape graphene nano-junction, the thermal conductance undergoes a transition with the increasing of the widths of the armchair nanoribbons. The thermal conductance decreases at low temperature region and increases at high temperature region. Meanwhile the thermal conductance of L-shape graphene nano-junction with included angle 150° decreases by increasing the widths of zigzag-edged nanoribbons in both low and high temperature regions. These thermal transport phenomena can be reasonably explained by analyzing the phonon transmission coefficient. We illustrate the mechanisms of thermal transport for different L-shaped graphene nano-junctions. The results provide significant physical models and theoretical basis for designing the thermal devices based on the graphene nano-junctions.

Published
2011
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43. The effect of stacked graphene flakes on the electronic transport of zigzag-edged graphene nanoribbons

Author

Zhong Jian-Xin, Zhang Mi, Ouyang Tao, Zhang Zai-Lan, and Chen Yuan-Ping

Subjects
Materials science, Condensed matter physics, Graphene, Fermi level, General Physics and Astronomy, Conductance, law.invention, symbols.namesake, Zigzag, Coupling effect, law, Green's function, symbols, Function method, Graphene nanoribbons
Abstract

The effect of stacked graphene flakes (GFs) on the electronic transport property of zigzag-edged graphene nanoribbon (ZGNR) is investigated. By using the Greens function method, we calculate the conductances of ZGNRs with two different stacked-type GFs. It is found that the coupling effect between ZGNRs and GFs can induce dips at the conductance profiles in two different stacked-types. For both stacked-types, the dips far away from the Fermi level are nearly overlapped. However, the position of conductance dip near the Fermi level depends on the stacked-type. In addition, we discuss the effect of geometric size of GF on the electronic transport property. The results show that with the increase of the size of GF, the dips far away the Fermi level in two stacked-types gradually move toward the Fermi level, while the discrepancy of the dips near the Fermi level is much evident. Our results indicate that the stacked GFs can effectively tune the electronic transport of ZGNR.

Published
2011
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47. Electronic structure and bonding mechanism of La-Ir-Si: A first-principles study

Author

Sun Li-Zhong, Zhong Jian-Xin, Zhang Kai-Wang, Chen Yuan-Ping, Liu Jun-min, and Yuan Hui-Qiu

Subjects
Superconductivity, Crystallography, Transition metal, Condensed matter physics, Coupling strength, Chemistry, General Physics and Astronomy, Superconducting transition temperature, Charge (physics), Electronic structure, Electronic band structure
Abstract

Using first-principles method, we studied the electronic structure and the bonding mechanism of La-Ir-Si materials. The results of the band structure and the density of the states indicated that the superconducting property of the La-Ir-Si system is determined by the p-d coupling strength between the transition element Ir-d and Si-p states of the material. In order to quantitatively describe the p-d coupling strength, we calculated the charge transfer during the bond process of the materials using the atom-in-molecule method. The results revealed that the superconducting transition temperature TC is linerly proportional to the atomic basin charges of Ir.

Published
2009
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49. A low-surface energy carbon allotrope: the case for bcc-C6.

Author

Yin, Wen-Jin, Chen, Yuan-Ping, Xie, Yue-E., Liu, Li-Min, and Zhang, S. B.

Abstract

Graphite may be viewed as a low-surface-energy carbon allotrope with little layer–layer interaction. Other low-surface-energy allotropes but with much stronger layer–layer interaction may also exist. Here, we report a first-principles prediction for one of the known carbon allotropes, bcc-C6 (a body centered carbon allotrope with six atoms per primitive unit), that should have exceptionally low-surface energy and little size dependence down to only a couple layer thickness. This unique property may explain the existence of the relatively-high-energy bcc-C6 during growth. The electronic properties of the bcc-C6 thin layers can also be intriguing: the (111), (110), and (001) thin layers have direct band gap, indirect band gap, and metallic character, respectively. The refrained chemical reactivity of the thin layers does not disappear after cleaving, as lithium-doped (Li-doped) 3-layers (111) has a noticeably increased binding energy of H2 molecules with a maximum storage capacity of 10.8 wt%. [ABSTRACT FROM AUTHOR]

Published
2015
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