25 results on '"Bando, Y."'
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2. Production and Characterization of Coaxial Nanotube Junctions and Networks of CNx/CNT
- Author
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Lepró, X., primary, Vega-Cantú, Y., additional, Rodríguez-Macías, F.J., additional, Bando, Y., additional, Golberg, D., additional, and Terrones, M., additional
- Published
- 2007
- Full Text
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3. Production and Characterization of Single-Crystal FeCo Nanowires Inside Carbon Nanotubes
- Author
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Elías, A. L., primary, Rodríguez-Manzo, J. A., additional, McCartney, M. R., additional, Golberg, D., additional, Zamudio, A., additional, Baltazar, S. E., additional, López-Urías, F., additional, Muñoz-Sandoval, E., additional, Gu, L., additional, Tang, C. C., additional, Smith, D. J., additional, Bando, Y., additional, Terrones, H., additional, and Terrones, M., additional
- Published
- 2005
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4. Intrinsic and Defect-Related Elastic Moduli of Boron Nitride Nanotubes As Revealed by in Situ Transmission Electron Microscopy.
- Author
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Zhou X, Tang DM, Mitome M, Bando Y, Sasaki T, and Golberg D
- Abstract
Boron nitride nanotubes (BNNTs) are promising for mechanical applications owing to the high modulus, high strength, and inert chemical nature. However, up to now, precise evaluation of their elastic properties and their relation to defects have not been experimentally established. Herein, the intrinsic elastic modulus of BNNTs and its dependence on intrinsic and deliberately irradiation-induced extrinsic defects have been studied via an electric-field-induced high-order resonance technique inside a high-resolution transmission electron microscope (HRTEM). Resonances up to fourth order for normal modes and third order for parametric modes have been initiated in the cantilevered tubes, and the recorded frequencies are well consistent with the theoretical calculations with a discrepancy of ∼1%. The elastic moduli of the BNNTs measured from high-order resonance is about 906.2 GPa on average, with a standard deviation of 9.3%, which is found to be closely related to the intrinsic defect as cavities in the nanotube walls. Furthermore, electron irradiation in HRTEM has been used to study the effects of defects to elastic moduli and to evaluate the radiation resistance of the BNNTs. Along with an increase in the irradiation dose, the outer diameter has linearly reduced due to the knock-on effects. A defective shell with nearly constant thickness has been formed on the outer surface, and as a result, the elastic modulus decreases gradually to ∼662.9 GPa, which is still 3 times that of steel. Excellent intrinsic elastic properties and decent radiation-resistance prove that BNNTs could be a material of choice for applications in extreme environments, such as those existing in space.
- Published
- 2019
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5. Statistically Analyzed Photoresponse of Elastically Bent CdS Nanowires Probed by Light-Compatible In Situ High-Resolution TEM.
- Author
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Zhang C, Cretu O, Kvashnin DG, Kawamoto N, Mitome M, Wang X, Bando Y, Sorokin PB, and Golberg D
- Abstract
We demonstrate that high resolution transmission electron microscopy (HRTEM) paired with light illumination of a sample and its electrical probing can be utilized for the in situ study of initiated photocurrents in free-standing nanowires. Morphology, phase and crystallographic information from numerous individual CdS nanowires is obtained simultaneously with photocurrent measurements. Our results indicate that elastically bent CdS nanowires possessing a wurtzite structure show statistically unchanged values of ON/OFF (photocurrent/dark current) ratios. Photocurrent spectroscopy reveals red shifts of several nanometers in the cutoff wavelength after nanowire bending. This results from deformation-induced lattice strain and associated changes in the nanowire band structure, as confirmed by selected area electron diffraction (SAED) analyses and density functional tight binding (DFTB) simulations. The ON/OFF ratio stabilities and photocurrent spectroscopy shift of bent CdS nanowires are important clues for future flexible electronics, optoelectronics, and photovoltaics.
- Published
- 2016
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6. Amorphous Phosphorus/Nitrogen-Doped Graphene Paper for Ultrastable Sodium-Ion Batteries.
- Author
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Zhang C, Wang X, Liang Q, Liu X, Weng Q, Liu J, Yang Y, Dai Z, Ding K, Bando Y, Tang J, and Golberg D
- Abstract
As the most promising anode material for sodium-ion batteries (SIBs), elemental phosphorus (P) has recently gained a lot of interest due to its extraordinary theoretical capacity of 2596 mAh/g. The main drawback of a P anode is its low conductivity and rapid structural degradation caused by the enormous volume expansion (>490%) during cycling. Here, we redesigned the anode structure by using an innovative methodology to fabricate flexible paper made of nitrogen-doped graphene and amorphous phosphorus that effectively tackles this problem. The restructured anode exhibits an ultrastable cyclic performance and excellent rate capability (809 mAh/g at 1500 mA/g). The excellent structural integrity of the novel anode was further visualized during cycling by using in situ experiments inside a high-resolution transmission electron microscope (HRTEM), and the associated sodiation/desodiation mechanism was also thoroughly investigated. Finally, density functional theory (DFT) calculations confirmed that the N-doped graphene not only contributes to an increase in capacity for sodium storage but also is beneficial in regards to improved rate performance of the anode.
- Published
- 2016
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7. Amorphization and Directional Crystallization of Metals Confined in Carbon Nanotubes Investigated by in Situ Transmission Electron Microscopy.
- Author
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Tang DM, Ren CL, Lv R, Yu WJ, Hou PX, Wang MS, Wei X, Xu Z, Kawamoto N, Bando Y, Mitome M, Liu C, Cheng HM, and Golberg D
- Abstract
The hollow core of a carbon nanotube (CNT) provides a unique opportunity to explore the physics, chemistry, biology, and metallurgy of different materials confined in such nanospace. Here, we investigate the nonequilibrium metallurgical processes taking place inside CNTs by in situ transmission electron microscopy using CNTs as nanoscale resistively heated crucibles having encapsulated metal nanowires/crystals in their channels. Because of nanometer size of the system and intimate contact between the CNTs and confined metals, an efficient heat transfer and high cooling rates (∼10(13) K/s) were achieved as a result of a flash bias pulse followed by system natural quenching, leading to the formation of disordered amorphous-like structures in iron, cobalt, and gold. An intermediate state between crystalline and amorphous phases was discovered, revealing a memory effect of local short-to-medium range order during these phase transitions. Furthermore, subsequent directional crystallization of an amorphous iron nanowire formed by this method was realized under controlled Joule heating. High-density crystalline defects were generated during crystallization due to a confinement effect from the CNT and severe plastic deformation involved.
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- 2015
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8. Molten Au/Ge alloy migration in Ge nanowires.
- Author
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Liu Q, Zou R, Wu J, Xu K, Lu A, Bando Y, Golberg D, and Hu J
- Abstract
Herein, we report time-resolved in situ transmission electron microscopy observation of Au particle melting at a Ge nanowire tip, subsequent forming of Au/Ge alloy liquid, and its migrating within the Ge nanowire. The migration direction and position of the Au/Ge liquid can be controlled by the applied voltage and the migration speed shows a linear deceleration in the nanowire. In a migration model proposed, the relevant dynamic mechanisms (electromigration, thermodiffusion, and viscous force, etc.) are discussed in detail. This work associated with the liquid mass transport in the solid nanowires should provide new insights into the crystal growth, interface engineering, and fabrication of the heterogeneous nanostructure-based devices.
- Published
- 2015
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9. Comparative fracture toughness of multilayer graphenes and boronitrenes.
- Author
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Wei X, Xiao S, Li F, Tang DM, Chen Q, Bando Y, and Golberg D
- Abstract
We report the comparative in situ fracture toughness testing on single-edge V/U-notched multilayer graphenes and boronitrenes in a high-resolution transmission electron microscope (HRTEM). The nanostructures of notch tips and fracture edges of the tested specimens are unambiguously resolved using HRTEM. By analyzing the notch tip stresses using finite element method, the fracture toughness of multilayer graphenes and boronitrenes is determined to be 12.0 ± 3.9 and 5.5 ± 0.7 MPa√m, respectively, taking into account the notch tip blunting effects.
- Published
- 2015
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10. Atomistic origins of high rate capability and capacity of N-doped graphene for lithium storage.
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Wang X, Weng Q, Liu X, Wang X, Tang DM, Tian W, Zhang C, Yi W, Liu D, Bando Y, and Golberg D
- Abstract
Distinct from pure graphene, N-doped graphene (GN) has been found to possess high rate capability and capacity for lithium storage. However, there has still been a lack of direct experimental evidence and fundamental understanding of the storage mechanisms at the atomic scale, which may shed a new light on the reasons of the ultrafast lithium storage property and high capacity for GN. Here we report on the atomistic insights of the GN energy storage as revealed by in situ transmission electron microscopy (TEM). The lithiation process on edges and basal planes is directly visualized, the pyrrolic N "hole" defect and the perturbed solid-electrolyte-interface configurations are observed, and charge transfer states for three N-existing forms are also investigated. In situ high-resolution TEM experiments together with theoretical calculations provide a solid evidence that enlarged edge {0002} spacings and surface hole defects result in improved surface capacitive effects and thus high rate capability and the high capacity are owing to short-distance orderings at the edges during discharging and numerous surface defects; the phenomena cannot be understood previously by standard electron or X-ray diffraction analyses.
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- 2014
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11. Revealing the anomalous tensile properties of WS2 nanotubes by in situ transmission electron microscopy.
- Author
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Tang DM, Wei X, Wang MS, Kawamoto N, Bando Y, Zhi C, Mitome M, Zak A, Tenne R, and Golberg D
- Abstract
Mechanical properties and fracture behaviors of multiwalled WS2 nanotubes produced by large scale fluidized bed method were investigated under uniaxial tension using in situ transmission electron microscopy probing; these were directly correlated to the nanotube atomic structures. The tubes with the average outer diameter ∼40 nm sustained tensile force of ∼2949 nN and revealed fracture strength of ∼11.8 GPa. Surprisingly, these rather thick WS2 nanotubes could bear much higher loadings than the thin WS2 nanotubes with almost "defect-free" structures studied previously. In addition, the fracture strength of the "thick" nanotubes did not show common size dependent degradation when the tube diameters increased from ∼20 to ∼60 nm. HRTEM characterizations and real time observations revealed that the anomalous tensile properties are related to the intershell cross-linking and geometric constraints from the inverted cone-shaped tube cap structures, which resulted in the multishell loading and fracturing.
- Published
- 2013
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12. Solid-solution semiconductor nanowires in pseudobinary systems.
- Author
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Liu B, Bando Y, Liu L, Zhao J, Masanori M, Jiang X, and Golberg D
- Abstract
Pseudobinary solid-solution semiconductor nanowires made of (GaP)(1-x)(ZnS)(x), (ZnS)(1-x)(GaP)(x) and (GaN)(1-x)(ZnO)(x) were synthesized based on an elaborative compositional, structural, and synthetic designs. Using analytical high-resolution transmission electron microscopy (HRTEM) and energy dispersive X-ray spectroscopy (EDS), we confirmed that the structure uniformity and a lattice match between the two constituting binary components play the key roles in the formation of quaternary solid-solution nanostructures. Electrical transport measurements on individual GaP and (GaP)(1-x)(ZnS)(x) nanowires indicated that a slight invasion of ZnS in the GaP host could lead to the abrupt resistance increase, resulting in the semiconductor-to-insulator transition. The method proposed here may be extended to the rational synthesis of many other multicomponent nanosystems with tunable and intriguing optoelectronic properties for specific applications.
- Published
- 2013
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13. Ultrahigh torsional stiffness and strength of boron nitride nanotubes.
- Author
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Garel J, Leven I, Zhi C, Nagapriya KS, Popovitz-Biro R, Golberg D, Bando Y, Hod O, and Joselevich E
- Subjects
- Nanotubes ultrastructure, Nanotubes, Carbon chemistry, Shear Strength, Stress, Mechanical, Boron Compounds chemistry, Nanotubes chemistry
- Abstract
We report the experimental and theoretical study of boron nitride nanotube (BNNT) torsional mechanics. We show that BNNTs exhibit a much stronger mechanical interlayer coupling than carbon nanotubes (CNTs). This feature makes BNNTs up to 1 order of magnitude stiffer and stronger than CNTs. We attribute this interlayer locking to the faceted nature of BNNTs, arising from the polarity of the B-N bond. This property makes BNNTs superior candidates to replace CNTs in nanoelectromechanical systems (NEMS), fibers, and nanocomposites.
- Published
- 2012
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14. Mechanical properties of Si nanowires as revealed by in situ transmission electron microscopy and molecular dynamics simulations.
- Author
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Tang DM, Ren CL, Wang MS, Wei X, Kawamoto N, Liu C, Bando Y, Mitome M, Fukata N, and Golberg D
- Abstract
Deformation and fracture mechanisms of ultrathin Si nanowires (NWs), with diameters of down to ~9 nm, under uniaxial tension and bending were investigated by using in situ transmission electron microscopy and molecular dynamics simulations. It was revealed that the mechanical behavior of Si NWs had been closely related to the wire diameter, loading conditions, and stress states. Under tension, Si NWs deformed elastically until abrupt brittle fracture. The tensile strength showed a clear size dependence, and the greatest strength was up to 11.3 GPa. In contrast, under bending, the Si NWs demonstrated considerable plasticity. Under a bending strain of <14%, they could repeatedly be bent without cracking along with a crystalline-to-amorphous phase transition. Under a larger strain of >20%, the cracks nucleated on the tensed side and propagated from the wire surface, whereas on the compressed side a plastic deformation took place because of dislocation activities and an amorphous transition., (© 2012 American Chemical Society)
- Published
- 2012
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15. Comparative studies on the electrical and mechanical behavior of catalytically grown multiwalled carbon nanotubes and scrolled graphene.
- Author
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Schaper AK, Wang MS, Xu Z, Bando Y, and Golberg D
- Abstract
The electrical and mechanical properties of multiwalled carbon nanotubes and of scrolled graphene structures, synthesized from iron-phthalocyanine in a catalytic chemical vapor deposition process, were investigated in situ in a transmission electron microscope. These experiments enabled us to get a more detailed quantitative picture of the peculiarities of the two different types of carbon nanostructures. The nanoscrolls showed superior conductance >10G(o), against ≤1G(o) of the nested tubes, and a much enhanced electric sustainability (∼10(8) A/cm(2)). While the pronounced nonlinear increase in current in the nested tube structure with increasing applied voltage is directly related to an increasing number of tubes involved, the electric breakdown has correspondingly been characterized by fractional ablation of the successive layers. Scrolls, on the contrary, do not show any fractional electric response. Mechanical bending has been found easier with scrolled graphenes than with nested tubes. This observation confirms the prediction of higher flexibility of the scroll structure in interesting phenomena like intercalation and electroactuation.
- Published
- 2011
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16. Phonon-assisted electron emission from individual carbon nanotubes.
- Author
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Wei X, Golberg D, Chen Q, Bando Y, and Peng L
- Subjects
- Computer Simulation, Electron Transport, Electrons, Particle Size, Models, Chemical, Nanotubes, Carbon chemistry, Nanotubes, Carbon ultrastructure
- Abstract
A question of how electrons can escape from one-atom-thick surfaces has seldom been studied and is still not properly answered. Herein, lateral electron emission from a one-atom-thick surface is thoroughly studied for the first time. We study electron emission from side surface of individual electrically biased carbon nanotubes (CNTs) both experimentally and theoretically and discover a new electron emission mechanism named phonon-assisted electron emission. A kinetic model based on coupled Boltzmann equations of electrons and optical phonons is proposed and well describes experimentally measured lateral electron emission from CNTs. It is shown that the electrons moving along a biased CNT can overflow from the one-atom-thick surface due to the absorption of hot forward-scattering optical phonons. A low working voltage, high emission density, and side emission character make phonon-assisted electron emission primarily promising in electron source applications.
- Published
- 2011
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17. "White graphenes": boron nitride nanoribbons via boron nitride nanotube unwrapping.
- Author
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Zeng H, Zhi C, Zhang Z, Wei X, Wang X, Guo W, Bando Y, and Golberg D
- Abstract
Inspired by rich physics and functionalities of graphenes, scientists have taken an intensive interest in two-dimensional (2D) crystals of h-BN (analogue of graphite, so-called "white" graphite). Recent calculations have predicted the exciting potentials of BN nanoribbons in spintronics due to tunable magnetic and electrical properties; however no experimental evidence has been provided since fabrication of such ribbons remains a challenge. Here, we show that few- and single-layered BN nanoribbons, mostly terminated with zigzag edges, can be produced under unwrapping multiwalled BN nanotubes through plasma etching. The interesting stepwise unwrapping and intermediate states were observed and analyzed. Opposed to insulating primal tubes, the nanoribbons become semiconducting due to doping-like conducting edge states and vacancy defects, as revealed by structural analyses and ab initio simulations. This study paves the way for BN nanoribbon production and usage as functional semiconductors with a wide range of applications in optoelectronics and spintronics.
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- 2010
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18. In situ TEM-STM recorded kinetics of boron nitride nanotube failure under current flow.
- Author
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Xu Z, Golberg D, and Bando Y
- Abstract
Joule-heating-induced failure of individual multiwalled boron nitride (BN) nanotubes is investigated in a high-resolution transmission electron microscope (TEM) equipped with a scanning tunneling microscope (STM) unit. Direct observation of the failure process indicates that it occurred via thermal decomposition of tubular layers from inside-out of a tube leaving amorphous ball-like boron-based nanoparticles behind. The electrical transport is well simulated by the thermionic field-emission model. The thermal decomposition temperature, which is deduced from a breakdown curve, shows a dependence on local electrical field; the higher the electrical field, the lower the decomposition temperature. This is attributed to partially ionic nature of a B-N bond.
- Published
- 2009
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19. Nanophotonic switch: gold-in-Ga2O3 peapod nanowires.
- Author
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Hsieh CH, Chou LJ, Lin GR, Bando Y, and Golberg D
- Abstract
A novel metal-insulator heterostructure made of twinned Ga2O3 nanowires embedding discrete gold particles along the twin boundary was formed through a reaction between gold, gallium, and silica at 800 degrees C during simple thermal annealing. The Au-in-Ga2O3 peapods spontaneously crystallized under phase separation induced by the formation of twin boundaries. The nanostructures were analyzed by field emission scanning (FESEM) and transmission electron microscopes (FETEM), and their photoresponse was investigated using a double-frequency Nd:YAG laser with a wavelength of 532 nm on a designed single-nanowire device. The surface plasmon resonance (SPR) effects of embedded Au nanoparticles are proposed to be responsible for the remarkable photoresponse of these novel structures.
- Published
- 2008
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20. Stepwise current-driven release of attogram quantities of copper iodide encapsulated in carbon nanotubes.
- Author
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Costa PM, Golberg D, Mitome M, Hampel S, Leonhardt A, Buchner B, and Bando Y
- Subjects
- Carbon chemistry, Drug Carriers, Electric Impedance, Microscopy, Electron methods, Microscopy, Electron, Transmission, Nanotechnology methods, Copper chemistry, Iodides chemistry, Nanotubes, Carbon chemistry
- Abstract
Encapsulated nanograins of copper iodide have been sequentially discharged from individual carbon nanotubes. Using a high resolution electron microscope equipped with a two-terminal electrical measurements unit, it was possible to manipulate the filling contents with precisions of a few attograms at a time. Changes in electrical resistance and filling ratio were followed in tandem and in real-time. It is shown that the pulsed release of the halide is directly related to the overall conductance of the filled nanotube.
- Published
- 2008
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21. Structure and cathodoluminescence of individual ZnS/ZnO biaxial nanobelt heterostructures.
- Author
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Yan J, Fang X, Zhang L, Bando Y, Gautam UK, Dierre B, Sekiguchi T, and Golberg D
- Abstract
We report on a controlled synthesis of two novel semiconducting heterostructures: heterocrystalline-ZnS/single-crystalline-ZnO biaxial nanobelts and side-to-side single-crystalline ZnS/ZnO biaxial nanobelts via a simple one-step thermal evaporation method. In the first heterostructure, a ZnS domain is composed of the heterocrystalline superlattice (3C-ZnS) N /(2H-ZnS) M [111]-[0001] with the atomically smooth interface between wurtzite and zinc blende ZnS fragments. High-spatial resolution cathodoluminescence studies on individual heterostructures for the first time reveal a new ultraviolet emission peak ( approximately 355 nm), which is not observed in separate ZnS or ZnO nanostructures. The present hererostructures are expected to become valuable not only with respect to fundamental research but also for a design of new broad-range ultraviolet nanoscale lasers and sensors.
- Published
- 2008
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22. Isotope effect on band gap and radiative transitions properties of boron nitride nanotubes.
- Author
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Han WQ, Yu HG, Zhi C, Wang J, Liu Z, Sekiguchi T, and Bando Y
- Subjects
- Boron chemistry, Computer Simulation, Isotopes chemistry, Macromolecular Substances chemistry, Materials Testing, Molecular Conformation, Particle Size, Surface Properties, Boron Compounds chemistry, Crystallization methods, Models, Chemical, Models, Molecular, Nanostructures chemistry, Nanostructures ultrastructure, Nanotechnology methods
- Abstract
We have carried out an isotope study on the band gap and radiative transition spectra of boron nitride nanotubes (BNNTs) using both experimental and theoretical approaches. The direct band gap of BNNTs was determined at 5.38 eV, independent of the nanotube size and isotope substitution, by cathodoluminescences (CL) spectra. At lower energies, several radiative transitions were observed, and an isotope effect was revealed. In particular, we confirmed that the rich CL spectra between 3.0 and 4.2 eV reflect a phonon-electron coupling mechanism, which is characterized by a radiative transition at 4.09 eV. The frequency red shift and peak broadening due to isotopic effect have been observed. Our Fourier transform infrared spectra and density functional theory calculations suggest that those radiative transitions in BNNTs could be generated by a replacement of some nitrogen atoms with oxygen.
- Published
- 2008
- Full Text
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23. Deformation-driven electrical transport of individual boron nitride nanotubes.
- Author
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Bai X, Golberg D, Bando Y, Zhi C, Tang C, Mitome M, and Kurashima K
- Abstract
In contrast to standard metallic or semiconducting graphitic carbon nanotubes, for years their structural analogs, boron nitride nanotubes, in which alternating boron and nitrogen atoms substitute for carbon atoms in a graphitic network, have been considered to be truly electrically insulating due to a wide band gap of layered BN. Alternatively, here, we show that under in situ elastic bending deformation at room temperature inside a 300 kV high-resolution transmission electron microscope, a normally electrically insulating multiwalled BN nanotube may surprisingly transform to a semiconductor. The semiconducting parameters of bent multiwalled BN nanotubes squeezed between two approaching gold contacts inside the pole piece of the microscope have been retrieved based on the experimentally recorded I-V curves. In addition, the first experimental signs suggestive of piezoelectric behavior in deformed BN nanotubes have been observed.
- Published
- 2007
- Full Text
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24. Field nanoemitters: ultrathin BN nanosheets protruding from Si3N4 nanowires.
- Author
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Zhu Y, Bando Y, Yin L, and Golberg D
- Abstract
Field emitters in nanoscale are important in micro/nanoelectronic devices. Here, we report a large scale synthesis and effective field emission of field nanoemitters. The integrated nanostructures of ultrathin BN nanosheets aligned on Si3N4 nanowires are prepared through a two-stage process. Si3N4 nanowires were previously synthesized through heating Si powder at 1500 degrees C under a N2 atmosphere. Ultrathin BN nanosheets were then deposited on Si3N4 nanowires by heating a homemade B-N-O precursor under a N2/NH3 atmosphere. The as-prepared nanofilaments act as cold electron emitters displaying excellent field emission performance owing to the untrathin and sharp edges of the protruding BN nanosheets.
- Published
- 2006
- Full Text
- View/download PDF
25. Carbon nanotubes as nanoreactors for fabrication of single-crystalline Mg3N2 nanowires.
- Author
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Hu J, Bando Y, Zhan J, Zhi C, and Golberg D
- Subjects
- Adsorption, Materials Testing, Molecular Conformation, Nanostructures chemistry, Nanostructures ultrastructure, Particle Size, Crystallization methods, Magnesium Compounds chemistry, Nanotechnology methods, Nanotubes, Carbon chemistry, Nanotubes, Carbon ultrastructure, Nitrogen chemistry
- Abstract
Due to fast decomposition of Mg3N2 in the presence of water in the atmosphere (Mg3N2+6H2O-->3Mg(OH)2+2NH3), the synthesis of single-crystalline Mg3N2 nanowires has been a challenge. Here, we demonstrate that carbon nanotubes may serve as nanoreactors for a simple thermal reaction process resulting in the first fabrication of high-quality, large-yield, single-crystalline Mg3N2 nanowires. The Mg3N2 nanowires are homogeneously sheathed over their entire lengths with very thin graphitic carbon tubular layers, which effectively prevent their decomposition (even when the samples are put into water or exposed to atmosphere for several months). We have systematically analyzed for the first time the Mg3N2 nanomaterial by means of transmission electron microscopy (TEM), high-resolution TEM, and electron diffraction. Successful fabrication of carbon sheath protected Mg3N2 nanowires may promote further experimental studies on their crystal structures and properties.
- Published
- 2006
- Full Text
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