Enhancing Hydrogen Adsorption by Metal Incorporation in Carbon Multi-Wall Nanotubes Produced by Continuous Hot Wire Chemical Vapor Deposition

A. C. Dillon, P. A. Parilla, J. L. Alleman, A. H. Mahan, K. E.H. Gilbert, K. M. Jones, M. J. Heben

Research output: Contribution to conferencePaperpeer-review

6 Scopus Citations

Abstract

The hydrogen storage properties of carbon single-wall and multi-wall nanotubes (SWNTs and MWNTs), graphitic nanofibers, and other nanostructured carbons have recently become the subject of considerable debate. Reported capacities range from ∼ 0-60 wt%. Hot wire chemical vapor deposition (HWCVD) has recently been adapted for a continuous growth process for high-density carbon MWNTs. Multi-wall nanotube growth is optimized in 1:5 CH4:Ar at 150 Torr with reactor temperatures of 400 and 550°C for static and flowing gases, respectively. Ferrocene is employed to provide a gas-phase catalyst. Highly graphitic nanotubes can be continuously deposited with iron content as low as 15 wt% and carbon impurities below thermal gravimetric analysis detection limits. The MWNTs are simply purified to ∼99.5 wt% with minimal structural damage and with a 75 wt% yield. Hydrogen adsorption is observed for low pressures at near ambient temperatures on the as-synthesized MWNTs containing iron nanoparticles. However, no hydrogen adsorption, is observed at near ambient temperatures for the purified MWNTs or for purified MWNTs that were subsequently combined with iron micro/nano-particles via sonication. These results indicate that an intimate metal/graphitic carbon interaction is required for unanticipated hydrogen adsorption at near ambient conditions.

Original languageAmerican English
Pages167-172
Number of pages6
DOIs
StatePublished - 2003
EventMaterials and Technology for Hydrogen Economy: Materials Research Society Symposium - Boston, Massachusetts
Duration: 1 Dec 20033 Dec 2003

Conference

ConferenceMaterials and Technology for Hydrogen Economy: Materials Research Society Symposium
CityBoston, Massachusetts
Period1/12/033/12/03

NREL Publication Number

  • NREL/CP-520-37304

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