A. Zambano scite author profile

We have experimentally determined the binding energies of Xe, CH4, and Ne on samples of closed-ended single-wall nanotube (SWNT) bundles. We find values for these quantities which are larger by approximately 75% on the SWNT samples than the values found for the same adsorbates on planar graphite. We have also determined the monolayer capacity of a SWNT sample using Xe and Ne adsorption. A comparison of all of our results leads us to conclude that none of the gases studied adsorb on the interstitial channels in the SWNT bundles.

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Determination of the binding energy of methane on single-walled carbon nanotube bundles

Weber

et al. 2000

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Binding energy and monolayer capacity of Xe on single-wall carbon nanotube bundles

2001

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Role of diffused Co atoms in improving effective exchange coupling inSm−Co∕Fespring magnets

et al. 2007

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In Sm-Co/ Fe exchange-spring magnet films, the magnetization reversal processes of constituent elements and layers were studied with an emphasis on the role of diffused Co atoms. Enhanced coupling effectiveness was observed in a film with a graded interface where significant Co diffusion into the Fe layer was observed by means of electron microscopy. Comprehensive insight into the magnetization reversal processes was obtained by combining micromagnetic simulation with element-and depth-resolved x-ray resonant magnetic scattering. The approach unambiguously identifies distinctive composition profiles across the graded interface and provides the magnetization behavior of the diffused Co.

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Inversion of Two-Band Superconductivity at the Critical Electron Doping of(Mg,Al)B2

et al. 2005

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Electron energy-loss spectroscopy (EELS) was combined with heat capacity measurements to probe changes of electronic structure and superconductivity in Mg(1-x)Al(x)B(2). A simultaneous decrease of EELS intensity from sigma-band hole states and the magnitude of the sigma gap was observed with increasing x, thus verifying that band filling results in the loss of strong superconductivity. These quantities extrapolated to zero at x approximately 0.33 as inferred from the unit cell volume. However, superconductivity was not quenched completely, but persisted with T(c) < 7 K up to about x approximately 55. Only the pi band had detectable density of states for 0.33 < or =x < or = 0.55, implying an inversion of the two-band hierarchy of MgB(2) in that regime. Since pi-band superconductivity is active in other materials such as intercalated graphite, implications for new materials with high T(c) are discussed.

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A. Zambano

Gases Do Not Adsorb on the Interstitial Channels of Closed-Ended Single-Walled Carbon Nanotube Bundles

Determination of the binding energy of methane on single-walled carbon nanotube bundles

Binding energy and monolayer capacity of Xe on single-wall carbon nanotube bundles

Role of diffused Co atoms in improving effective exchange coupling inSm−Co∕Fespring magnets

Inversion of Two-Band Superconductivity at the Critical Electron Doping of(Mg,Al)B2

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