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Science

World's First Single-Atom-Thick Fabric 390

neutron_p writes "Researchers at The University of Manchester have made the world's first single-atom-thick fabric, which reveals the existence of a new class of materials and may lead to computers made from a single molecule. They call it graphene, because it's 'webbed' by extraction of individual planes of carbon atoms from graphite crystal. The nanofabric belongs to the family of fullerene molecules, which were discovered during the last two decades, but is the first two-dimensional fullerene."
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World's First Single-Atom-Thick Fabric

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  • Can it cut things? (Score:5, Interesting)

    by CoreyGH ( 246060 ) on Thursday October 21, 2004 @11:53PM (#10595366) Homepage
    Seriously, does this mean the edge of the fabric is really sharp? Can it cut through stuff?
    • by Amiga Lover ( 708890 ) on Thursday October 21, 2004 @11:56PM (#10595387)
      I want to know, if you had a sheet of this stuff about 1cm by 1cm... could you see it? does light permeate it? refract off it in rainbows?
      • by Dancin_Santa ( 265275 ) <DancinSanta@gmail.com> on Thursday October 21, 2004 @11:58PM (#10595402) Journal
        Since it is only one type of molecule and only one molecule thick, the refractive index of the material would be constant. So if it had any color at all, it would be a constant color, not a rainbow like oil or a prism produces.
        • Diffraction grating is what ?
        • by MillionthMonkey ( 240664 ) on Friday October 22, 2004 @12:18AM (#10595498)
          Fullerenes conduct electricity, so its refractive index is most likely negative and it would be opaque if it were thicker. But the skin depth is on the order of a micron so individual fullerene sheets are transparent.
        • by gardyloo ( 512791 ) on Friday October 22, 2004 @01:20AM (#10595749)
          Except glass (usually) has a constant index of refraction (as does bubble film, which you're apparently thinking of). It's the fact that there is chromatic dispersion (simply: different frequencies of light--the colors--travel at different speeds in the medium (giving different refraction angles, and, therefore, different paths and pathlengths). So even though the index of refracton is constant for a _given_frequency_, the fact that the index changes for different frequencies gives the colors (along with multiple reflections from front and back surfaces).

          The fact that this stuff is only one molecule thick is much more persuasive. In fact, very thin bubbles are completely transparent to light, because the light cannot refract if the film is less than about a wavelength thick. Since molecules (chains and polymers get a little tricky, of course) are generally much, much smaller than a visible wavelength, this stuff will probably be virtually invisible, unless, as another poster pointed out, it's extremely highly conductive (which would cause a skin-depth effect and probably do more complicated things to light).
          • by Mattcelt ( 454751 )
            Maybe I'm wrong here, but doesn't refraction have to do with the absorption and re-emission of photons by atoms? It's my understanding that the presence of a color means that all other wavelengths have been absorbed by the material, leaving only those that constitute the color in question. So isn't this subject to the same inherent photon-manipulating characteristics as other carbon atoms?

            What am I missing here?
            • by gardyloo ( 512791 ) on Friday October 22, 2004 @04:01AM (#10596196)
              Yes, refraction is due to a change in group speed between media: if in one medium, the constituents interact a lot more with the light than the constituents of the other medium, the group speed in the highly interacting medium tends to be slower than in the other. Because of the requirement that various boundary conditions at the mediums' interface must be matched, the wavefronts tend to bend at the interface, and one has refraction.
              You're right, in that absorption of all colors but, say, blue by some object will make that object look blue. BUT one may also separate colors into different portions of an object -- the light of different colors has simply ended up in different spots, but hasn't been permanently absorbed or attenuated (as in interference colors in bubbles, or oil slicks, etc.). One way to obtain this is to simply reflect light multiple times off of two parallel (or nearly parallel) surfaces, as in a bubble or a pane of glass. Very little of the light is really absorbed, just shuttled from place to place.

              I think that we're probably just thinking of different "complementary" pictures of light -- you're focusing (agh!) on the photon, discrete picture, and I'm focusing on the continuum, wavelike picture. I'm essentially trying to scale down what I know about wave mechanics to spatial regimes where those wave mechanics get pretty strange (due to the wavelength vs. molecular size discrepancy). I think you're applying some scattering theory (or at least some good intuition) to the problem. Of course, if we're both careful, we should end up with exactly the same answer.

              So isn't this subject to the same inherent photon-manipulating characteristics as other carbon atoms?
              Oh, absolutely. However, one must recognize that things can scatter light in very strange ways depending on their spatial relationships to each other. Carbon atoms in graphite and diamond are identical, but their locations relative to each other make all the difference between opaque grey, and transparent brilliance. Same with water vapor in the air (humidity in the air doesn't scatter light by itself, but get those water molecules clustered together in big enough drops -- say, in a cloud -- and they scatter light quite effectively).

              Basically, what I'm getting at is that you have to have some semblance of order on a scale comparable to the wavelength of light you want to interact with, to ever scatter that light. Because this "cloth" is so thin, I doubt it'll interact with the light much at all, unless you have wavefronts incident on it at grazing angles -- then you have the chance of the light interacting with it over larger spatial domains, and getting some scattering.

              I dunno. Time to look at boobies. They scatter quite well. Especially when they hear geek-talk.
            • doesn't refraction have to do with the absorption and re-emission of photons by atoms?

              No, that's just what a lot of physics classes teach. ;) Atoms can only absorb discrete frequencies of radiation and wouldn't provide the continuous responce across large parts of the EM spectrum like we see in the index of refraction of materials. The materials actually cause an effectivfe change in the permitivity and permeability of the space they occupy which results in the change in the speed of light (c = 1/sqrt(

              • by Idarubicin ( 579475 ) on Friday October 22, 2004 @08:07AM (#10597142) Journal
                Atoms can only absorb discrete frequencies of radiation and wouldn't provide the continuous responce across large parts of the EM spectrum like we see in the index of refraction of materials.

                I agree with your point that this material certainly shouldn't be treated like it has a bulk index of refraction--a monatomic layer is definitely in the realm of weird quantum effects.

                It should be noted that this system can't be treated like distinct atoms, however. It's effectively one giant molecule, with a very complicated electron cloud surrounding a layer of nuclei. In the ideal case where this system is perfectly flat, you (er, a solid state physics grad student) can probably come up with a reasonable idea of what its absorption and emission spectra look like. (I wouldn't be surprised if a creature like this showed not insignificant fluorescence.) On the other hand, as soon as you start to bend this stuff, or introduce small defects, or do anything else to it, it gets a lot more complicated. You get a whole pile of nonlinear effects, and I wouldn't be surprised of there were broadband absorption. (Actually, that absorption could be used to tell you all about the stresses and defects in a particular sample of the material. Can I have my patent now?)

    • by nels_tomlinson ( 106413 ) on Friday October 22, 2004 @12:17AM (#10595489) Homepage
      ... does this mean the edge of the fabric is really sharp?

      Can you keep it stiff? Paper will cut you if you can keep it stiff enough to slide your finger along the edge with a little pressure, but silk cloth of the same thickness won't because it isn't stiff.

      If you can figure out a way to make it rigid, you'll have a nifty new razor blade.

    • by k98sven ( 324383 ) on Friday October 22, 2004 @12:51AM (#10595654) Journal
      Seriously, does this mean the edge of the fabric is really sharp? Can it cut through stuff?

      Nope. It's not rigid.

      But.. if you could add a layer on top of that layer, juxtaposed by the minimal amount (half of a ring, see this picture [benbest.com] of graphite crystal structure), and then add another layer, and another..

      Then you could form a 'perfectly sharp' knife.

      I'm not sure how durable it'd be though, because the inter-layer bonds in graphite are rather weak.
      • While it may not be rigid by itself, if it attached to two ends and stretched it might be.
      • by Linknoid ( 46137 ) on Friday October 22, 2004 @08:52AM (#10597492) Homepage
        Then you could form a 'perfectly sharp' knife.

        That's so...stone age. Seriously :-) Obsidian can be fasioned into blades with an edge that's only 1 atom thick (I've seen pictures of an electron micrograph in a book, I wish I could find some online to post). Obsidian in fact is used in some cases as surgeon's scalpels because it can be made so much sharper than steel.

    • by mog007 ( 677810 ) <Mog007@g m a i l . c om> on Friday October 22, 2004 @07:09AM (#10596828)
      All I know is that it's the perfect material for pants when you're getting a lap dance.
  • Whoo Hoo! (Score:5, Funny)

    by I am the Bullgod ( 797123 ) on Thursday October 21, 2004 @11:53PM (#10595371)
    J-Lo has already commissioned a dress made out of the stuff for the Oscars.
  • by HonkyLips ( 654494 ) on Thursday October 21, 2004 @11:55PM (#10595377)
    Kramer: I've cut slices so thin, I couldn't even see them.
    Elaine: How'd you know you cut it?
    Kramer: I guess I just assumed...
  • Finally! (Score:3, Funny)

    by Bill_Royle ( 639563 ) on Thursday October 21, 2004 @11:55PM (#10595379)
    A reason to get behind wearable computers!
  • by Dancin_Santa ( 265275 ) <DancinSanta@gmail.com> on Thursday October 21, 2004 @11:56PM (#10595383) Journal
    Something that small and fine could possibly become airborne and eventually irritate allergic responses.

    Not to mention that consumption of the material could lead to carcinogenic effects.

    Before we start throwing around phrases like "wonder material" and "the future is now", perhaps we should take a closer look at the health risks involved in making/using these practically invisible materials.
    • by CrazyGringo ( 672487 ) on Friday October 22, 2004 @12:02AM (#10595417)
      First off, fullerenes are strong enough to build a space-elevator with, I don't think they'll come apart so easy.

      Secondly, if you are eating fabric on a regular basis, cancer risk might be the least of your problems.

    • The material is made of carbon atoms. I don't think you'll find many people allergic to carbon, since most everyone I've met has been "carbon-based".
      • by Anonymous Coward on Friday October 22, 2004 @12:25AM (#10595537)
        Read this: http://en.wikipedia.org/wiki/Fullerene [wikipedia.org] , especially the "Possible dangers" section.
        An experiment by Eva Obersdörster at the Southern Methodist University in Dallas which introduced fullerenes into water at concentrations of 0.5 parts per million found that largemouth bass suffered a "17-fold increase in cellular damage in the brain tissue" after 48 hours. The damage was of the type lipid peroxidation, which is known to impair the functioning of cell membranes. There were also inflammatory changes in the liver and activation of genes related to the making of repair enzymes.
      • by dasunt ( 249686 ) on Friday October 22, 2004 @01:00AM (#10595686)

        The material is made of carbon atoms. I don't think you'll find many people allergic to carbon, since most everyone I've met has been "carbon-based".

        However, if this material breaks down into tiny, airborne pieces, it could by-pass the lung's filtering system and lodge itself in the tissue.

        Black lung disease [wikipedia.org] is caused by coal dust, and coal is nothing more then carbon and hydrocarbons, both basic biological building blocks for life on earth. Its just that the coal dust gets lodged in the lungs, and the body can't remove it. The irritation then causes problems.

      • CO (Score:3, Insightful)

        by Rufus88 ( 748752 )
        Yeah, and we breathe oxygen too. So putting them together can't be harmful either, right?

        I guess that's why carbon monoxide is so safe.
    • by I am the Bullgod ( 797123 ) on Friday October 22, 2004 @12:09AM (#10595451)
      Don't get thrown off by the term "fabric". If you read the article, you'll realize that the applications of this are mainly in integrated circuit fabrication. As far as the health and environmental issues, we're talking about a pure carbon lattice. With this process carbon can act as a semiconductor without dopants such as arsenic, so C-based semiconductors are actually "greener" than current silicon-based chips.
    • by Sir Holo ( 531007 ) * on Friday October 22, 2004 @12:17AM (#10595492)

      Something that small and fine could possibly become airborne and eventually irritate allergic responses.

      Nah, it has to be micron-scale (1000x larger) for your lungs to recognize it as foreign, and eject it. Like it does with dust.

      Not that that's a good thing. People get asbestosis and silicosis for just this reason. Sharp particles that are beneath detection become embedded. And if they aren't broken down and stay sharp, they cut, cut, cut at the cellular level for the rest of your life.

      As for graphene becoming airborne, lodging in the lungs, and never breaking down, who knows?
      • What experiance do we have with stuff smaller than dust? I would guess that before we had experience with asbetosis, or the coal miner's black-lung (carbon by the way) we might have ignored it as having no possible effect.
        Opps - didn't read your last sentence - yes it may be a problem. Are we not scientists? Do we not believe in actual data?
        Experimentalists of the world unite!
    • My guess is that that's not the biggest health problem. Think for a moment - mono-molecular fabric meets soft lung tissue at high velocity. If you started breathing in mono-molecular fluff or dust, the least of your worries is going to be whether it'll cause a rash.
    • simply existing in a universe filled with cosmic rays leads to carcinogenic effects.

      if people stopped to consider risks, we'd still be living in caves and dying by the age of 20.

      short term risks lead to long term security.
  • can you tear this? (Score:4, Interesting)

    by the_2nd_coming ( 444906 ) on Thursday October 21, 2004 @11:56PM (#10595388) Homepage
    I mean, the fabrics we know can be torn because the atoms are clumped into partitions that we shove together, but this fabric is one layer of chemically bonded carbon atoms. that is some tough stuff.
    • by SiliconEntity ( 448450 ) on Friday October 22, 2004 @02:02AM (#10595869)
      It would be really, really weak, because it is so thin. The slightest breeze would destroy it, if you made a macroscopically sized piece. And of course you couldn't see it, or feel it. You wouldn't even know it was there without special instruments.

      As bonds go, the inter-atomic bonds in this fabric are strong; but there's only one layer! Compared to like ten million atomic layers in a typical fabric. The carbon bonds aren't *that* much stronger that you can make a ten million times thinner (and weaker) piece and still have it be strong.

      It's the same with nanotubes; they're as strong as tubes get, considering that they're only a nanometer in diameter. But compared to the weakest macroscopic thread you could imagine, an individual nanotube is far weaker. Proposed nanotube cables would use trillions of them in parallel to carry a load.
      • by HalfStarted ( 639977 ) on Friday October 22, 2004 @09:30AM (#10597849) Journal
        While you are probably right about it not being strong because there is only one layer it is much stronger than you think. When you tear a piece of paper of an other fabric you are not breaking atomic bonds you are separating fibers that are mushed or spun together.

        A better comparison would be thinking about tearing a piece of aluminum foil. It is very hard to cause it to separate under tension and you have to add sheering forces to get a fracture to start.
  • Monosheet? (Score:5, Funny)

    by Solder Fumes ( 797270 ) on Thursday October 21, 2004 @11:57PM (#10595394)
    So...there's lots of stuff out there discussing "monoatomic filament" as a sci-fi concept. Supposedly the sharpest thing possible, and a dangerous weapon.

    How strong is this stuff? If you stretched a band of it between two points, say along the edge of a sword, would you have something that could produce the world's nastiest paper cuts?
    • A monoatomic filament is only sharp if the bonds between its atoms are stronger than the bonds within the structure it is trying to cut through I would think.

      hell, surely there is a possibility that a monoatomic filament would simply pass through solid matter without contacting it??
  • Neato (Score:5, Funny)

    by Anonymous Coward on Friday October 22, 2004 @12:03AM (#10595429)
    I hope they can make condoms out of this stuff.
  • by weighn ( 578357 ) <weighn@g m a i l . com> on Friday October 22, 2004 @12:04AM (#10595432) Homepage
    I can hear the advertising slogan already.

    you wont know you're wearing it.
    And if you're a truely a geek, she wont know you're in it.

  • by eingram ( 633624 ) on Friday October 22, 2004 @12:05AM (#10595434)
    Here it is (below):





    Cool stuff, huh?
  • Sounds like even stronger and lighter carbon fiber to me...

    Also, I wonder: could it be an even better material for the space elevator ribbon than nanotubes? After all, "ribbon" (which is how they describe the elevator cable in the articles I've read) suggests a flat string rather than a round one.
  • massively useful (Score:3, Interesting)

    by Doc Ruby ( 173196 ) on Friday October 22, 2004 @12:14AM (#10595472) Homepage Journal
    I want a 1m^2 sheet that electrostatically rolls up into a 1cm x 1m rod, then contracts like a telescoping antenna into a 1cm x 1mm disc. Then it can do all its various functions in rod and sheet size, and clip to my earring when I'm done. At such a low mass, its logic should be rechargeable by swinging while I walk, like a self-winding watch. The future is cool. If I can get a towel made of this stuff, I'll be the hoopiest frood in the Galaxy!
  • With the proper planning, could you use this to put a computer on a sheet of paper masked as a letter home? Imagine if spy agencies had some of this stuff...
  • by DoorFrame ( 22108 ) on Friday October 22, 2004 @12:20AM (#10595508) Homepage
    I've always wanted to write the world's tiniest novel. Now all I need is a monoatomic pencil and a monoatomic eraser. Or maybe just a monoatomic word processor.

    When will science catch up with my worthwhile ideas? When?
  • Brrrr.... (Score:4, Funny)

    by corngrower ( 738661 ) on Friday October 22, 2004 @12:21AM (#10595513) Journal
    I don't think it'll be very useful in winter coats. Maybe for ladies' swimwear.
  • Two-Dimensional (Score:2, Insightful)

    by Arzach ( 692634 )
    "The nanofabric belongs to the family of fullerene molecules, which were discovered during the last two decades, but is the first two-dimensional fullerene." Two-Dimensional? Surely a molecule has at least three dimensions...
  • I'm guessing that comes without a floppy drive. Or a USB port.
  • by Anonymous Coward on Friday October 22, 2004 @12:55AM (#10595669)
    That Hans Christian Andersen was so far ahead of his time he wrote about this graphene stuff hundreds of years ago. [ivyjoy.com]
  • Capacitors? (Score:3, Interesting)

    by Lisandro ( 799651 ) on Friday October 22, 2004 @01:47AM (#10595828)
    I wonder if something like that could be used to make very high capacity unpolarized capacitors, just like the regular foil ones (an isolator sandwiched by two conductor sheets and rolled into a can). The only way to get high capacitances practically (above 1uF) is to use electrolytics, which have quite a share of disadvantages.
  • by panurge ( 573432 ) on Friday October 22, 2004 @02:33AM (#10595952)
    I'm beginning to think that nowadays every tech article has to include at least 1 really stupid claim, either so the authors can laugh at the stupid journos who pass them on uncritically, or because it's the bit the journalist will think he understands and that will make a headline.
    Any kind of machinery requires differentiated structures, and anything involving electricity requires localised anisotropy - or how will you get your current flows separate in order to do anything useful? DNA has a differentiated structure but it is not a machine, it is a recording medium (parenthetically, it's just as well the RIAA wasn't around when life evolved: "What do you mean, you can replicate DNA? That's illegal file-sharing!") and the machines that do something useful with it are all multi-molecular. It's unlikely a few billion years (sorry, George) of evolution will be seriously wrong about this. I don't mind Slashdot contributors including marketoid claims in headers, but they might at least quarantine them in quotes and put a [sic] at the end so we know that they know what we know.
  • by tod_miller ( 792541 ) on Friday October 22, 2004 @04:18AM (#10596237) Journal
    Condoms!

    Molecule thin!

    Get them while they are hot!

    2050: Durex extra sensitive using nanotech technology with built into internal wifi nano-webcam and apache-hhtpd. Runs linux.
  • Manchester or UMIST (Score:3, Informative)

    by doodlelogic ( 773522 ) on Friday October 22, 2004 @05:40AM (#10596480)
    The article linked to the wrong university website, the new one is here. [manchester.ac.uk]

    The University of Manchester is really still two universities, in the process of merger. As an ex Owens student, I'm intrigued as to whether it was their physics teams that found this or UMIST's down the road... Both good teams and I'm very proud they're still doing such good work.
  • by cascadingstylesheet ( 140919 ) on Friday October 22, 2004 @06:45AM (#10596736) Journal

    Was it Piers Anthony? A whole *town* had women wearing transparent, incredibly thin bodysuits.

    The story was set in the 50's, I think. The whole moral structure of this town had changed, because women could just, er, pop stuff right back out, without the slightest danger or even evidence. Some guy wandered into the town and was amazed at what he found.

    Of course, most of modern society is that town now anyway, but without the bodysuits :(

    • Was it Piers Anthony? A whole *town* had women wearing transparent, incredibly thin bodysuits.

      The story was set in the 50's, I think. The whole moral structure of this town had changed, because women could just, er, pop stuff right back out, without the slightest danger or even evidence. Some guy wandered into the town and was amazed at what he found.

      Of course, most of modern society is that town now anyway, but without the bodysuits :(


      Up Schist Crick, Piers Anthony 1972

      Remember the ending? The guy, u

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