German Scientists Create Aerographite, the Lightest Material in the World

I used to make aerogels (a related class of materials) in high school; allow me to give a (hopefully accurate) layperson's overview.<p>Aerogels formerly held the record for least dense solid. They're not gels, but they're called aerogels because they're made from gels. As the name "aero" implies, they're mostly air, giving them incredible strength-to-weight ratios and insulating properties. Silica aerogels are translucent and quite amazing to hold; it's like holding a cloud.<p>Aerogels are made from colloids (a.k.a. gels), which are long chains of polymers formed in water. Free-floating around in the water, they form very long, intricate, 3-D maze-like structures. If you've ever made JELL-O, you've made (and eaten) a colloid. It’s the intricate structure of the colloid which keeps the suspended water from spilling out.<p>Silica aerogels are formed by removing the water from a silica gel, leaving only the maze like structure behind. This structure is very delicate, and if you attempt to evaporate the water out near room temperature/pressure, the capillary action of water will collapse the structure like a dried out jellyfish. However, if you heat and pressurize the system past the critical point, the water becomes a supercritical liquid and it can be removed without pulling the rest of the material inwards.<p>It appears that what they’ve done here is similar, except they use a multi-step process to deposit carbon on the colloid, then remove the colloid completely, leaving nothing but a carbon maze. I presume they can't make colloids out of carbon directly, hence the multistep process.

That's pretty cool. But I'm a bit confused... FTA, <i>the aerographite density is 0.2 mg/cm3.</i><p>From Wikipedia on Aerogel (another very lightweight solid) [1], <i>The lowest-density aerogel is a silica nanofoam at 1 mg/cm3, which is the evacuated version of the record-aerogel of 1.9 mg/cm3. The density of air is 1.2 mg/cm3 (at 20 °C and 1 atm). Only the recently manufactured metallic microlattices have a lower density at 0.9 mg/cm3.</i><p>How are they computing the density of the aerographite such that it doesn't float away (having 1/6 the density of air)? Are they only considering the mass of the carbon and not the internal air?!<p>[1] <a href="http://en.wikipedia.org/wiki/Aerogel" rel="nofollow">http://en.wikipedia.org/wiki/Aerogel</a>

Here is the press release with further information, video and images:<p><a href="http://www.uni-kiel.de/aktuell/pm/2012/2012-212-aerographit-e.shtml" rel="nofollow">http://www.uni-kiel.de/aktuell/pm/2012/2012-212-aerographit-...</a><p>Interesting potential for batteries (quoted from above link):<p><i>"Due to its unique material characteristics, Aerographite could fit onto the electrodes of Li-ion batteries. In that case, only a minimal amount of battery electrolyte would be necessary, which then would lead to an important reduction in the battery's weight. This purpose was sketched by the authors in a recently published article. Areas of application for these small batteries might be electronic cars or e-bikes. Thus, the material contributes to the development of green means of transportation."</i>

<a href="https://en.wikipedia.org/wiki/Aerographite" rel="nofollow">https://en.wikipedia.org/wiki/Aerographite</a><p><i>Owing to its interconnected tubular network structure, aerographite resists tensile forces much better than other carbon foams as well as silica aerogels. It has a very low Poisson ratio, as demonstrated by a complete shape recovery of a 3-mm-tall sample after it was compressed down to 0.1 mm. Its ultimate tensile strength (UTS) depends on material density...</i><p>How soon will we see this used instead of metal frameworks or latex foam? In aircraft wings, car seats, etc?<p>Even more interesting: <i>Upon external compression, the conductivity increases, along with material density</i>. Pressure-sensitive aircraft wings? Car seats that know what their occupants weigh?

The research on light and strong materials is key to one day developing space elevators.<p><a href="http://en.wikipedia.org/wiki/Space_elevator#Cable" rel="nofollow">http://en.wikipedia.org/wiki/Space_elevator#Cable</a><p>I don't know what the strength of this material is or its breaking length (a breaking length of 5,000 km is required for a space elevator), the abstract doesn't say so, but research like this is really exciting.

Aerogel (aka "solid smoke") was the lightest so far, at 1mg/cc[1] .<p>The density of air is 1.2 mg/cc.<p>FTA: "The substance weighs just 0.2 milligrams per cubic centimeter"<p>So why doesn't this thing just fly away, if its density is 0.2 mg/cc ?<p>[1] <a href="http://en.wikipedia.org/wiki/Aerogel" rel="nofollow">http://en.wikipedia.org/wiki/Aerogel</a>

&#62;Think of the Aerographite as an ivy-web, which winds itself around a tree. And than take away the tree.<p>I would totally expect this stuff to be transparent based on the description. Shows what I know.

IANAP, but if this material is "jet black", i.e. absorbs most light, and also highly conductive, wouldn't it also be a great component for organic solar cells? Graphene is apparently already an interesting candidate for this application, promising lower costs of manufacture (if not higher efficiency).

If they could turn it into a thread imagine what it could do for the fashion industry. Amazing dresses that flow in the wind even when there is no wind. I'd be worried about strength though.

I had a dream last week that scientists would someday be able to remove the Higgs Boson from atoms to make truly weightless materials. I should patent that.<p>As far as "flying away", from the video embedded in the linked article, you can see the aerographite is barely able to sit still on the table before the rod is introduced - one of them is about to fly away just sitting there. It just "looks" extremely light.

Think about this for a second. If you wear a tracksuit made of this you'll be able to jump higher than when you're naked.