Liquid Sponges Extract Hydrogen From Water 113
New submitter gaelfx writes: Researchers at Glasglow University have an interesting method for separating the hydrogen out of water: Liquid Sponges. Most methods of extracting the hydrogen involve some form electrolysis, but these generally require some pretty expensive materials. The researchers claim that they can accomplish this using less electricity, cheaper materials and 30 times faster to boot. With both Honda and Toyota promising hydrogen fuel cell cars in Japan within the next few years (other manufacturers must be considering it as well, if not as publicly), does this spell a new future for transportation technology?
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Re:Nature (Score:5, Insightful)
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It still takes more energy to separate the hydrogen from the oxygen than it releases by reacting.
Do you mean, "Why not this instead of photosynthesis?"
And that's because hydrogen is chemically unstable and hard to store compared to sugars. Neither of those are good things for living creatures.
Re:Nature (Score:5, Funny)
And that's because hydrogen is chemically unstable and hard to store compared to sugars. Neither of those are good things for living creatures.
Exactly. Plants learned *that* lesson long before we did with the Hindenburg [wikipedia.org]. (If you listen very carefully to the video, you can hear all the plants laughing at our naiveté in the background.)
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This joke falls kinda flat because it reads like you're trying to make a point. Like maybe some kinda "nature is always right" naturalistic fallacy.
We still do lighter than air flight with helium(and in the case of weather balloons, hydrogen). Nature has exactly zero precedent for lighter-than air flight, but it's not a bad idea.
Lighter-than-surrounding medium flight (Score:3)
Most fish regulate their buoyancy using air-bubbles inside their bodies. Water is not air, but for a precedent it would do because Archimedes' law applies to gases and liquids equally...
And even in the air — the way plants like dandelions spread their seed... Well, they aren't lighter than the surrounding air of the same volume, but they are light enough to not require any power for flight.
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They do require power for flight, though. The power is wind energy.
Re: Nature (Score:3, Informative)
Promulgating the Hindenburg myth. The gas bag itself was flammable; it wouldn't have mattered what gas was in it, when it disintegrated. The burning of the released hydrogen gas caused none if the damage; it went up, and the specific heat was low. It was gone in a moment. The fire you see in the video is burning diesel fuel and oil.
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If you were to believe MythBusters, it was likely caused by a combination of both. The paint AND the Hydrogen. The result wasn't nearly as destructive when they tested either one without the other.
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Prove it
Oh yes, let's time travel to this specific historical event and objectively test what happened.
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I remember the Mythbusters looked at the Hindenberg. It's been a while so I may be misremembering, but if I recall, their replication of the skin did burn with an inert gas, but it burned more spectacularly with hydrogen (I suspect that they were able to get a different and more energetic reaction with hydrogen present).
However GGP does have a point; even if the bag had been full of helium, once it caught, the ship was going down.
Especially: The paint. (Score:2)
The gas bag itself was flammable; it wouldn't have mattered what gas was in it, when it disintegrated
In particular: The paint. It contained a mix of powdered aluminum and iron oxide pigments, in sufficient concentration to maintain a redox reaction.
You and I know this mixture as "thermite". It's really hard to get the reaction started - but an electric discharge can do it. (They tried to tether it with an electrical storm approaching. That would make one hell of a spark when the charged envelope comes
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And when plants learned that lesson, one of them must have surely exclaimed: "Oh, the botany!!"
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Call me a cynic, but shouldn't you have learned the difference between "of" and "have" by now?
The contraction " 've" (should've) is not the same as "of", and never has been.
*sigh* My grade school English teacher would be laughing at me right now. Now get off my damned lawn!!
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Second, Nature knows what it's doing, it's man that's got shit backwards. Nature is was able to extract the energy from oxygen, rather than hydrogen. The current biological configuration is acting on levels higher than simple materialism can afford. No need to propel biology with explosions of the type produced by hydrogen. See here [youtube.com] for a (very basic) comparison of oxygen vs hydrogen.
Re: Nature (Score:1)
Have course I will. Now that you have pointed it out I feel ashamed have myself. I feel as if someone just dumped a refreshing bucket have grammar on top have my head. Thank you!
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Call me a cynic, but wouldn't nature of done this long ago as a primary source of energy for oceanic life? Take Hydrogen and combine with oxygen. Lots-o-energy with a simple path of ingestion. It's like, inhaling food!
First of all hydrogen production does not generate energy, it consumes energy.
Scientists are interested in hydrogen as an energy storage medium. It is unlikely that life forms would use hydrogen as an energy storage medium since hydrogen gas can practically only be stored inside a metal tank, or at least a tank lined with an internal layer of metal. Metal requires smelting which is highly incompatible with how life forms develop, so you're not going to find plants or animals with metal parts.
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Your a cynic.
Is the expense of electrolysis the main inhibitor? (Score:2)
Or is it the comparably low demand for hydrogen, due to its dangerous and/or inconvenient differing characteristics with hydrocarbons?
I mean, either way, it's good news, but in one case it's opening a possible revolution, and in the other it's just nice to have.
Re:Is the expense of electrolysis the main inhibit (Score:5, Interesting)
I am interpreting your first question as "Is the expense of electrolysis the main inhibitor of a hydrogen-fuel economy?" I believe the answer is "sorta, but not really." The cheapest way to get hydrogen is from natural gas. The problem is that the whole reason to move to a hydrogen economy is to become carbon-neutral. If you use natural gas mines, you defeated the purpose. So to that point, a cheaper form of electrolysis might help.
Your second question is really a chicken-vs-egg question. There's low demand, because there aren't hydrogen-powered vehicles. But that is because it is difficult to store the hydrogen with sufficient density to make a car that can travel a long-enough distance. Compressing it takes time, wastes energy, and makes the tanks heavy and expensive. The next generation of attempts stores the hydrogen chemically. But bear in mind that there is already a really really good way to store hydrogen chemically. In the US, we call it "gasoline" and it is great because all you have to do is burn it, and it releases the energy from the hydrogen-carbon bond! Awesome! Perfect! Right? Ooops, that darned carbon-neutral thing again...
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fairly sure Iceland maintains a fleet of Hydrogen fueled vehicles, and they're just a stone's throw from Scotland.
The question is: what is a reasonable distance? most EV have that question too.
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A stone's throw.... for a volcano.... maybe.
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A stone's throw.... for a volcano.... maybe.
I specified the delivery, not the mechanism.
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The question is: what is a reasonable distance? most EV have that question too.
I would say a "reasonable distance" would cover the daily needs of 90% of the general public. I accept that my needs are atypical, thus I will have to wait for an EV that meets my needs.
Re:Is the expense of electrolysis the main inhibit (Score:5, Informative)
The next generation of attempts stores the hydrogen chemically.
I'm not sure if it qualifies as "the next generation" when it has been studied since well before my now-adult children were born.
Skepticism with respect to hydrogen exists in part because some of us have heard this tune before. Storage of hydrogen in metal sponges is nothing new, and they have some very nice theoretical properties, including reasonable volumetric energy density, which is a big problem for hydrogen.
Getting up to 1/5 the volumetric density of fossil fuels--which is the likely upper limit--would make hydrogen cars more than competitive with electric vehicles. But so far no one has managed that, despite continuous work on the problem.
For some reason TFA doesn't say anything about the long history of storing hydrogen in metal sponges, or make clear what makes this one different, although one can guess that as a liquid there are likely metal particles in suspension and that gives a huge surface area advantage.
It's almost as if the articles were written by junior staff members with no actual knowledge of hydrogen storage technology, but since we live in a "knowledge based economy" where STEM skills are in incredibly high demand there is no way reputable news organizations like the BBC would do anything like that, right?
Re:Is the expense of electrolysis the main inhibit (Score:5, Informative)
Not really. Natural gas is methane - CH4. It's about 35-85x more potent greenhouse gas than CO2 [wikipedia.org]. If you're converting methane to hydrogen, then converting that to CO2, you're not reducing the amount of carbon in the atmosphere, but you're still helping reduce the greenhouse effect.
All this is of course contingent on what would have happened to the methane if you weren't using it as fuel. Methane is primarily a byproduct of oil drilling. Until recently energy prices were low enough that it wasn't cost-effective to capture it, so oil companies just burned it as it came up the wells (those fires you see on top of long poles at oil fields). So since it was going to be converted to CO2 anyway, converting it to hydrogen to be used in fuel cells is actually carbon neutral. If oil production drops enough that we need to drill for methane specifically to keep up production, then it starts being carbon positive.
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What is done with the carbon when the methane (CH4) is converted to hydrogen, can it be captured and stored?
Because using the hydrogen itself wouldn't cause CO2 - there is no C or O in pure H.
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PS it is 100% not carbon neutral that logic is utterly fallacious.
"So since it was going to be converted to CO2 anyway, converting it to hydrogen to be used in fuel cells is actually carbon neutral."
Either way - NOT carbon neutral.
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There are a few changes that jump out at me as being significant:
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Well the argument that it is better for the environment never really holds much.
So to get people to switch we need the following.
1. Cheaper then our current sources of energy. A little cheaper we can get some traction, a lot cheaper we will get good movement.
2. Economics 101 low demand means low price. The issue is low supply (in terms of it being packaged) that is keeping its price high. Making a technology to do this cheaper will help improve supply because people can produce Hydrogen and make money of
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Why is it always "econ 101" with you guys? Reducing things to the basics is a great way to engage in reductionistic dismissal of reality. Simple economic policy to place externality costs onto energy producers could radically change what defines "the cheapest".
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This is not the thread to engage me this point. Go back to the one where you made the stupid simplistic statement that didn't adequately reflect reality, and defend what you actually said.
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Seems to me you are arguing FOR econ 101, when you think you're arguing against it.
To be able to do a "real" supply vs. demand comparison, you DO need all costs involved included.
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What I'm saying is that these guys go "Supply/demand the end" without consider how those factors are considered. It's far too simplistic and it's like the a sphere of uniform density in a frictionless vacuum is to physics, in that it helps you understand the concepts, but applying it so simplistically is going to get you bad results.
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Steven Chu: I think, well, among some people it hasnâ(TM)t really shifted. I think there was great enthusiasm in some quarters, but I always was somewhat skeptical of it because, right now, the way we get hydrogen primarily is from reforming [natural] gas. Thatâ(TM)s not an ideal source of hydrogen. Youâ(TM)re giving away some of the energy content of natural gas, which is a very valuable fuel. So thatâ(TM)s one problem. The other problem is, if itâ(TM)s for transportation, we don
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Electrolysis is just a way of putting that energy back into water to conver
Re:No, not really (Score:5, Insightful)
Neither article makes any claim of a need for chemical purity of the water. What would coarse filter + reverse osmosis levels of purity be insufficient?
Do you have a third source of information or is this baseless dismissal?
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Okay, making up universal principles of industry was not a direction I expected this to go.
You're crazy.
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Please provide an industrial process that makes something useful that doesn't tightly control its inputs.
And *I'm* crazy. Wow. The delusions you have!!
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Okay, sure. There's this thing, you'll learn about if you ever got exposed to the most basic of engineering principles. They're called "Tolerances" where variation in inputs to the process are expected to be within certain bounds. These bounds do not demand perfect ingredients. I mean, you get microscropic tolerances in processes like making microchips, and have clean rooms. But these are the exceptions.
You'll find, for example, that the quality of wood boards varies greatly, and yet we build buildings
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Do you remember the party where you said
This was entirely wrong, and declaring I that "lose" because I correctly identified how the real world does things doesn't have any bearing on me calling you on outright bullshit.
And you'll forgive me if I'm not concerned with your opinions of my posting.
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I'm glad you made up my mind for me, because I was pretty sure you're an idiot decrying new technology for imagined reasons, using a facile justification, then declaring yourself the victor in an internet debate.
Good job on catching that typo, though. My credibility is ruined now.
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The existence of measurable standards is not the same as hyper-purity, you doofus
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Yes, "very pure" and "hyper pure" are semantically the same. Don't whine at me because I used a prefix where you used an adjective. That's the most pedantic useless complaint I've heard.
You doofus.
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Re:No, not really (Score:5, Informative)
You still need very pure water or you poison the process. Where's that water coming from? How do you collect the gaseous hydrogen? You still need to liquify it and all the emrittlement and cryogenic issues are still there.
Even if hydrogen gas is free, it makes no sense as an energy carrier for cars.
They don't collect the gaseous hydrogen in the electrolyzer; they soak it up with a "liquid sponge" ("a recyclable redox mediator (silicotungstic acid) " according to the article's abstract. [sciencemag.org] In principle at least, hydrogen could be stored and transported in this form (a liquid sponge soaked with hydrogen).; the hydrogen can be catalytically released (wrung out of the liquid sponge) when needed. Whether such a system could be built with a practical size, weight, and cost for use in vehicles is another matter.
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Actually, the "improvement" in MPG is from capturing what would otherwise be wasted energy (idle, coasting, etc. ya' know, the things hybrid vehicles have been doing for a very long time.)
This ignores the big problem of hydrogen, leakage (Score:5, Interesting)
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This discovery allows the hydrogen to be stored and created at regular atmospheric pressure, since it is stored as a liquid acid. So at least during storage and production, I think this discovery solves that.
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Any form of gas has that problem. Methane and gas from wells also have a high leakage rate.
Doesn't mean we don't use LNG or methane in fuel cells, though.
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Yeah, right around the time that the sun is boiling our water anyway.
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This ignores the big problem of hydrogen, leakage. Currently about 10% to 20% of all hydrogen produced is lost to leakage. This has serious environmental ramifications. Hydrogen leakage will cause bigger and longer lasting holes in the ozone layer. By making hydrogen production cheaper and easier it just makes the leakage problem worse. http://www.nature.com/news/200... [nature.com]
Your own article says "Although its environmental benefits would still far outweigh any drawbacks.", so maybe you're overreacting a bit.
Electrolysis still required, says TFA (Score:5, Informative)
The process uses a liquid that allows the hydrogen to be locked up in a liquid-based inorganic fuel. By using a liquid sponge known as a redox mediator that can soak up electrons and acid we’ve been able to create a system where hydrogen can be produced in a separate chamber without any additional energy input after the electrolysis of water takes place.
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My bad :P
Re:Electrolysis still required, says TFA (Score:5, Informative)
Another Summary: Scheduling hydrogen release... (Score:3, Informative)
I've found this difficult to understand what has been accomplished, and I found this other summary helpful. From sciencemag.org:
Scheduling hydrogen release from water
Photosynthesis splits water to provide protons and electrons for plant growth; oxygen is a by-product. When chemists split water, they're also more interested in making fuel, and the simplest product is hydrogen (a combination of protons and electrons). One challenge is keeping the reactive hydrogen and oxygen product streams separate. Rausch et al. present a scheme that captures the protons and electrons in a molecular cluster of silico-tungstic acid. Later, they expose the cluster to platinum, coaxing the acid into releasing hydrogen. Eliminating the mixing risk increases the potential for household use.
Very intriguing... (Score:3)
This appears to be a power-efficient process that on the back end produces a bluish liquid which contains a high quantity of hydrogen. When this liquid is combined with a metallic catalyst it then releases the hydrogen at normal atmospheric pressure/temperature without requiring any further electricity.
I wonder if the bluish liquid could serve as a hydrogen storage mechanism that is both easily transportable and transferable between containers such as liquid fuels today? Does production scale to industrial quantities? Is it non-toxic and non-explosive (while kept away from a catalyst)? Lots of questions not touched on in the articles.
However, for hydrogen vehicles, the ability to transfer useful quantities of hydrogen fuel at room-temperature liquid and normal pressure could be a real boon. Let's hope this provides a possible path to practical hydrogen vehicles.
It's the law. (Score:2)
What they actually accomplished (Score:4, Informative)
Or in even simpler terms
Note that platinum is still required, but it works 30 times more efficiently. Also the pressure needed is much lower.
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silicotungstic acid? (Score:2)
Si. OH WOW
No. Batteries are the future for trans technology (Score:1)
We're roughly on the 2nd' generation of car battery technology. Advances are being made in labs seemingly at a weekly bases, with reports of 2-3x power storage, 10 times charge speed etc etc.
Here is just 1 example of literally dozens: http://www.gizmag.com/dual-carbon-fast-charging-battery/32121/
Most people won't want a Leaf that has a 80 mile range. Will they buy one with a 240 mile range with a lower cost? One that when you drive it into your garage it recharges over wireless (which the tech is already he
It is a solvent for hydrogen. (Score:2)
To free hydrogen from water, you need energy, not low quality energy like heat but high quality energy in the form of electricity. So there is no special advantage there. You still go through hydrolysis. But instead of releasing hydrogen as a gas, you dissolve it in this oxide solvent. The liquid can be stored at room temp and pressure without the danger of leaks, fire or explosion. When you
hydrogen is for transfer (Score:2)
the real problem with renewable energies (lik
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I think there's a lot of value in looking at how to use hydrogen generated with renewables, especially when the source like solar or wind is capable of generating when the power isn't needed. During those periods the efficiency of energy conversion to hydrogen almost seems like it shouldn't matter because the energy is essentially free -- we can generate it but don't have any other use for it.
Other Manufacturers? Like BMW? (Score:2)
All those small other manufacturers may be either ignoring it or doing secret research projects the depths of their garages.
Or the article simply ignored the one company which has been quite publicly showing off a hydrogen car for the past 7 years. The BMW Hydrogen 7 [wikipedia.org]
Hydrogen Works Great (Score:2)
Next... (Score:2)
someone needs to engineer a conversion unit that is safe from accidents. This process relies upon a controlled release of hydrogen from the solvent by a careful (and small) reaction with a catalyst. If the catalyst component were suddenly submerged in the liquid solvent (such as might happen if a car bumper forced the component through a containment wall), there would be an uncontrolled release of hydrogen that would be accelerated from any heat resulting from combustion of that hydrogen.
Gasoline doesn't co