Biomedical Engineering Reference
In-Depth Information
2005
“Hydrogen
Materials Science and Chemistry of Carbon Nanomaterials”:
,
Krym, Sevastopol',
Ukraina,
(
9
th
Intern.
Conf.
ICHMS'
, Crimea, Sevastopol, Ukraine).
112. Reichenauer G., Rzepka M., and Bauer E.,
2005
et al.
(2006).
Extended
Abstracts, Carbon
(Aberdeen, Scotland, UK); The British Carbon
Group, The Robert Gordon University, paper 10A1_Reichenauer, pdf.
Document.
2006
2.3
Part II—On Some Experimental Proofs
of the Hydrogen Multilayer Intercalation
with Carbonaceous Nanostructures:
The Importance of Supersdsorbent
Development for Fuel-Cell-Powered
Vehicles
2.3.1
Introduction
The analysis of some recent experimental and theoretical data on
the problem of hydrogen on-board storage shows the need to carry
out further basic studies and to initiate a constructive discussion
on the keynote physical aspects (open questions) of the hydrogen
sorption by carbon-based nanomaterials. In this context especially
important is the hydrogen multilayer intercalation in carbonaceous
nanostructures for the development of super-adsorbents for fuel-
cell-powered vehicles.
Some results of studies on the hydrogen multilayer intercalation
in carbonaceous nanostructures are presented and analyzed here,
and the relevance for the development of super-adsorbents for fuel-
cell-powered vehicles, i.e., storage materials satisfying most of the
DOE targets is discussed.
2.3.2 On the Specific Intercalation of Atomic Hydrogen
into Graphene Layers
A real possibility of hydrogen intercalation into near-surface
graphene layers of highly oriented pyrolytic graphite (HOPG) has
been shown in a series of experimental studies [5-8]. Studies [5]
on the atomic hydrogen accumulation in HOPG samples and surface
