Possible Breakthrough In Hydrogen Energy

destinyland writes "MIT researchers have developed a method of splitting a water molecule by emulating the way blue-green algae separates oxygen from hydrogen. One chemistry professor called it 'an extremely clever piece of work' that addresses 'the nanoscale organization of the components.' Using sunlight rather than electricity to make hydrogen from water could greatly improve the efficiency of the process. The hydrogen can be stored for generating electricity or burned as fuel for cars. The project is being led by the winner of a 2004 MacArthur Foundation genius grant, who uses genetically engineered viruses as templates for nanoscale electronic components. 'Suddenly, I wondered, what if we could assemble materials like the abalone does — but not be limited to one element?'" Here is the press release from MIT; the research paper is available only to subscribers of Nature Nanotechnology (or those willing to part with $18).

efficiency

[wizardforce]

This is from what I've read on the subect, quite impressive in terms of how it works however, this isn't a technology that is very likely capable of exceeding the efficiency of a few other methods of producing Hydrogen. 10% solar => Hydrogen efficiency would be impressive for a biological system but well within reach of other technologies like solar thermal + water thermochemical cracking This technology might be of use if alternatives remain comparatively expensive.

Re:efficiency

As someone who both worked on this biological route and saw this thesis defense (FYI, this is a dupe of an earlier story), and someone who is now working on the solar thermal route, I agree so heartily I was amazed to actually read this comment here. This is exactly the correct analysis -- extremely cool science, brilliant work, but no chance of being an actual engineering solution. As far as "comparitively expensive", the solar thermal routes we work on use metal oxides like FeO/Fe2O3 which is completely recovered while the biological route we use incorporates IrO2... and degenerates after 4-5 cycles. This seems like a no-brainer to me. However, the quantum efficiency trends due to cross coupling, the gel method of suspending wires, etc were all absolutely fascinating ideas.

I should probably start logging in at some point so that people actually read my comments. A shame I can't be bothered to remember my password.

Re:efficiency

[wizardforce]

The UT-3 cycle + the ferrite cycle might work better in combination. Ferrite water cracking until the material is passivated at which point UT-3 takes over in a separate reaction chamber

Dupe! And Unobtianium Alert!!!

[Black+Gold+Alchemist]

This story appears to be a dupe.

Iridium, a form of unobtainium, is used. This costs upwards of $13,000 per kg. About 3 tons are produced a year.

Over-rated

Some genuinely incredible work has come out of the labs at MIT; however, the work described in this article is pedestrian. Frankly, Prof. Belcher is a seriously over-rated, one-trick pony. Don't get me wrong, it's a hugely impressive trick - essentially directed evolution of viruses to get their capsid (i.e., proteinaceous component) to selectively bind to [whatever], but she applies it to whatever the current hot topic is, such as the photocatalytic splitting of water, and has absolutely done it to death. It's her hammer for the world of research nails.

Some of you may recall one of her papers a few years ago on virus-based lithium ion batteries. That work was also Belcher's brainchild, used the exact same techniques as are found in this Nature Nanotech paper, and was also ridiculously over-rated.

The problem with MIT is shameless self-promotion - and it's self-perpetuating because people (even the MIT professors spouting their own greatness) believe it. Another example is Robert Langer, whose work is fine but unremarkable. However, because he's so well known and great at self-promotion, he gets papers in Science/Nature/etc. As a result, his fame continues and the accolades continue to pour in.

It's frustrating to watch, knowing that fame and accolades are often undeserved when brilliant work from lesser known researchers goes unnoticed, but there's really no solution other than to point out when particular academics get more recognition than they deserve and hope that others reading agree and spread the word.

Hydrogen == Battery

You're not getting energy "out" of water. You're getting energy out of solar radiation.

Yup, hydrogen is just a battery: you charge it by removing the oxygen, then discharge it by burning it (which recombines the oxygen atoms and reforms water).

(unless, of course, you're doing fusion, then hydrogen IS a power source)

Re:What happens at night?

[drinkypoo]

That is a concern for vehicles, certainly. Not so much for buried tanks.

It is less of a concern in stationary installations, but you have to compress the gas, and since we're using methane as a comparison, it's dramatically easier to store methane simply because it's a larger molecule, and it's easier to use due to lack of problems with hydrogen embrittlement. You can convert existing gasoline engines to run on methane, though nobody does because it's not sufficiently available. Instead, they do it with propane, from which the difference is probably a re-jetting, or perhaps a change in working pressure. But converting existing engines to hydrogen would fail because the metals are not treated to resist embrittlement, and extended use would lead to engine destruction. Presumably, valves would go first, and frequently.

The simple truth is that hydrogen is not a satisfactory energy storage mechanism until we figure out how to better store it. And it's looking more and more like the storage mechanism is going to be something with a lot of surface area rather than an empty tank. That means more mass overall, further reducing the potential lead of hydrogen over batteries. Given that practical fuel cells are perpetually 5-10 years away, the total efficiency of a system using hydrogen today would be extremely poor due to the use of an internal combustion engine, and since hydrogen engines are in their infancy compared to gasoline or diesel engines, they could be expected to be highly unreliable for a time.

Or in short, it makes far more sense to make biodiesel right now than to do anything else. In the medium term, perhaps full-EVs will be the best value proposition for most people; If the Nissan LEAF takes off it could bring about real change. Maybe in twenty or thirty years we can use hydrogen.