Pressure and Temperature Effect on Hydrogen Sorption of Carbon Material

Lyudmila V. Gulidova; Natalya A. Dubrova; Andrey M. Lider

doi:10.4028/www.scientific.net/AMR.1085.280

Paper Titles

Influence of Refractory Metal Oxide Ultrafine Particles on the Structure and Mechanical Properties of High-Manganese Steel
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Acrylate Hydrogel Modification Using a Cross-Linking Agent for Increasing Multilayer Glazing Flame Resistance
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Effect of High Intensity Pulsed Ion Beam of Carbon on Subsurface Layers of Zirconia Ceramics
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Grain Bending at Deformation of the Steel and Arrangement of Internal Stresses
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Pressure and Temperature Effect on Hydrogen Sorption of Carbon Material
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Changing of the Structural-Phase State and Mechanical Properties of VT-23 Titanium Alloy under Surface Treatment by Intense Flux of Copper Ions
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Structural Phase State and Mechanical Properties of the Si-Al-N Coatings with Different Concentration Ratio of Al and Si
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Influence of the Grain Size on the Dispersion Strengthening of VT1-0 Alloy Implanted with Aluminum Ions
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Features of Stress Changes in the Alloy Ti₅₀Ni_48,7Mo_0,3V₁ under Loading in a Wide Temperature Range
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1085Pressure and Temperature Effect on Hydrogen...

Pressure and Temperature Effect on Hydrogen Sorption of Carbon Material

Abstract:

The paper presents the experimental results of saturation of the carbon material containing nanotubes with hydrogen from the gas. The dependences of hydrogen concentration from pressure (from 0 to 8 atmospheres), at the same temperature for adsorption (-30 degrees Celsius) and different temperatures for desorption were obtained. The temperature has an influence on sorption-desorption process and sorption properties of carbon material. The amount of residual hydrogen depends on saturation parameters.

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Periodical:

Advanced Materials Research (Volume 1085)

Pages:

280-283

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1085.280

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Online since:

February 2015

Authors:

Lyudmila V. Gulidova, Natalya A. Dubrova, Andrey M. Lider

Keywords:

Carbon Nanotube (CN), Desorption, Hydrogen Storage, Sorption

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