 |
There are currently, 302 guest(s) and 0 member(s) that are online.
You are Anonymous user. You can register for free by clicking here
| |
| |
Researchers solve decade-old mystery of hydrogen storage material
Posted on Thursday, February 28, 2008 @ 20:11:26 UTC by vlad
|
|
Environmentally friendly hydrogen gas fueled vehicles can dramatically
reduce greenhouse gas emissions and lessen the country’s dependence on
sources of fossil fuel. Though several hydrogen vehicles exist on the
market today, there is still much room for improvement in the way that
hydrogen is stored on-board the vehicle. With current technologies,
hydrogen gas storage tanks have to be as large as or larger than the
trunk of a car to carry enough gas to travel only one to two hundred
miles.
While liquid hydrogen is
denser and takes up less space, it is very expensive and difficult to
produce. It also reduces the environmental benefits of hydrogen
vehicles. Widespread commercial acceptance of these vehicles will
require finding the right material that can store hydrogen gas at high
volumetric and gravimetric densities in reasonably sized light-weight
fuel tanks.
Researchers at the UCLA Henry
Samueli School of Engineering and Applied Science, with the use of
molecular dynamics simulations, have solved a decade old mystery that
could one day lead to commercially practical designs of storage
materials for use in hydrogen gas fueled vehicles. The study appears on
the Proceedings of the National Academy of Sciences web site on February 27.
In 1997, it was discovered that adding a small amount of titanium
to a well-known metal hydride, sodium alanate, not only lowers the
temperature of hydrogen release from the material but also allows for
an easy refueling and storage of high density hydrogen at reasonable
pressures and temperatures. In fact, the weight percent of stored
hydrogen was instantly doubled in comparison with other inexpensive
materials.
“Nobody really understood what
the titanium did. The chemical processes and the mechanisms were really
a mystery,” said Vidvuds Ozolins, associate professor of material
science and engineering, a member of the California NanoSystems
Institute, and lead author of the study.
With computers and the power of basic physics, chemistry and
quantum mechanics, Ozolins’ group decided to take a step back and
analyze the sodium alanate in its pure form, without added titanium.
The group analyzed the atomic processes occurring in the material and
what happens to the chemical bond between the hydrogen and the material
at the temperatures of hydrogen release. The computation gave the
researchers information that would have been very difficult to obtain
experimentally.
The computation suggested a reaction mechanism that is essential
for the extraction of hydrogen from the material which involves
diffusion of aluminum ions within the bulk of the hydride. By comparing
the calculated activation energies to the experimentally determined
values, Ozolins’ group found that aluminum diffusion is the key rate
limiting process in materials catalyzed with titanium. Thus, titanium
facilitates processes in the material that are essential for turning on
this mechanism and extracting hydrogen at lower temperatures.
“This method and this knowledge can now be used to analyze other
materials that would make for better storage systems than sodium
alanate. We are still on the fundamental end of the study. But if we
can figure this out computationally, the people with the technology in
engineering can figure out the rest,” said Hakan Gunaydin, a UCLA
graduate student in Ozolins’ lab and another one of the study’s
authors.
“Sodium alanate in itself is a prototypical complex hydride with a
reasonable storage density and very good kinetics. Hydrogen goes in and
comes out quickly but it wouldn’t be practical for a car simply because
it doesn’t contain enough hydrogen. So that’s why we are so interested
in understanding how the hydrogen comes out, what happens exactly and
how we can take this to other materials,” said Ozolins.
What Ozolins’ group, along with UCLA chemistry and biochemistry
professor Kendall Houk, also a member of the California NanoSystems
Institute, hopes to do now is to apply the methods and lessons learned
to those materials that would make for a commercially practical
hydrogen gas storage system. They hope their findings will one day
facilitate the design and creation of an affordable and environmentally
friendly hydrogen vehicle.
Source: University of California - Los Angeles
Via: http://www.physorg.com/news123307288.html
|
| |
|
Don't have an account yet? You can create one. As a registered user you have some advantages like theme manager, comments configuration and post comments with your name.
| |
|
| "Researchers solve decade-old mystery of hydrogen storage material" | Login/Create an Account | 2 comments | Search Discussion |
|
| | The comments are owned by the poster. We aren't responsible for their content. |
|
|
|
No Comments Allowed for Anonymous, please register |
|
Re: Researchers solve decade-old mystery of hydrogen storage material (Score: 1)
by malc on Friday, February 29, 2008 @ 00:36:23 UTC
(User Info | Send a Message) http://web.ukonline.co.uk/mripley | I don't believe hydrogen is the solution for vehicles. I can see compressed air being the solution. The vast majority of car journeys are short and so the 200-300Km range of a tank of compressed air is perfect. No doubt this could improve over time.
There is simply no comparison, as far as safety is concerned, when considering hydrogen over air! |
|
|
Nanoparticles could make hydrogen cheaper than gasoline (Score: 1)
by vlad on Friday, February 29, 2008 @ 19:58:57 UTC
(User Info | Send a Message) http://www.zpenergy.com |  by R.Colin Johnson/ EE Times/
PORTLAND, Ore. — The hydrogen economy is getting a shot in the arm from
a start-up that says its nanoparticle coatings could make hydrogen easy
to produce at home from distilled water, and ultimately bring the cost
of hydrogen fuel cells in line with that of fossil fuels.
QuantumSphere Inc. says it has perfected the manufacture of highly
reactive catalytic nanoparticle coatings that could up the efficiency
of electrolysis, the technique that generates hydrogen from water.
Moreover, the coatings could also eliminate the need for expensive
metals like platinum in hydrogen fuel cells. [www.eetimes.com]
Boasting 1,000 times the surface area of traditional materials, the
coatings can be used to retrofit existing electrolysers to increase
their efficiency to 85 percent--exceeding the Department of Energy's
goal for 2010 by 10 percent. The scheme holds the promise of 96 percent
efficiency by the time cars powered by hydrogen fuel cells [www.eetimes.com] hit automobile showrooms, according to the Santa Ana, Calif., company.
"Instead of switching 170,000 gas stations over to hydrogen, using our
electrodes could enable consumers to make their own hydrogen, either in
the garage or right on the vehicle," said Kevin Maloney, president,
chief executive officer and co-founder of QuantumSphere. "Our
nanoparticle-coated electrodes make electrolysers efficient enough to
provide hydrogen on demand from a tank of distilled water in your car."
The first commercial product inspired by QuantumSphere's technology
will debut later this year: a battery using a cathode coated with the
startup's nanoparticles, thereby increasing its energy density 5x over
alkaline cells and boosting power by 320 percent. The first commercial
nonrechargeable batteries with this increased capacity will be
announced by an as-yet-unnamed major U.S. battery maker in the second
half of 2008.
QuantumSphere also claims to be able to improve rechargeable
nickel-metal-hydride batteries to the point where they perform better
than the less environmentally friendly lithium-ion batteries popular
today.
QuantumSphere's plan is first to retrofit existing electrolysis
equipment with its nanoparticle electrodes to boost efficiency. Next,
it intends to partner with original equipment manufacturers to design
at-home and on-vehicle electrolysers for making hydrogen from water for
fuel cells. Finally, the company wants to work with fuel cell makers to
replace their expensive platinum electrodes with inexpensive
stainless-steel electrodes coated with nickel-iron nanoparticles.
QuantumSphere's nanoparticles are available in four
formulations: nickel cobalt, iron cobalt, nickel iron and silver
copper. According to the Freedonia Group Inc. (Cleveland), the
nanoparticles can be sold directly into the catalyst metals market,
which it predicts will edge up to $4.7 billion this year.
More: http://www.eetimes.com/showArticle.jhtml?articleID=206801669 [www.eetimes.com]
Via KeelyNet News [www.keelynet.com]
|
|
|
|
|
