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New Superconductor Found "Immune To Magnetism"

Posted by kdawson on from the north-south-it's-all-the-same-to-me dept.

Lisandro sends in news that testing of the new class of superconductors we discussed a while back (compounds of iron, lanthanum, and rare earths) has turned up a major surprise: magnetism doesn't shut off the superconducting state. Magnetic fields represent one of three factors that limit expanded applications for superconductors (the others are current density and temperature dependence.) The research will appear in Nature; here's a preprint (PDF).

14 of 201 comments (clear)

  1. Re:Another limit? by fyngyrz · · Score: 4, Informative

    You've reached the wrong conclusion; if it isn't ductile, you can't use it for wires that bend; however, you can certainly use it for wires that follow nonlinear paths.

    --
    I've fallen off your lawn, and I can't get up.
  2. Re:Another limit? by mshannon78660 · · Score: 4, Informative

    That's a limitation, rather than a limit. Not being ductile makes it less convenient to use. With magnetism, current density and temperature, the superconductivity disappears as each value reaches a critical point (the limit).

  3. Re:Another limit? by JoeBuck · · Score: 4, Informative
    The original superconductors were metals for the most part, but only work at liquid helium temperatures. Then a new class of high-temperature superconductors were discovered, some of which work at liquid nitrogen temperatures; this second class is often called "cuprate superconductors" and they could be described as ceramic. The lack of ductility isn't as bad a problem as the low tolerance for magnetic field that still superconducts at 45 tesla (basically the strongest magnetic field the experimenters could produce).

    Since flowing current creates a magetic field, you can't use cuprate superconductors to carry large currents. Evidently a completely new class of materials has been discovered.

  4. Summary is flat-out wrong. by caffeinated_bunsen · · Score: 5, Informative

    Read that preprint, or at least look at the pictures -- specifically Fig. 6. It's a measurement of the upper critical field (i.e. the magnetic field that destroys the superconducting state) versus temperature. The 90% line (where the resistivity is 90% of its normal-state value) does indeed go off the graph at low temperatures; it extrapolates to about 60 T for 5 K.

    There's a big difference between "This material has a very high critical field" (which is what the article said) and "This material has no critical field" (which is what the summary said).

    --

    Bugrit! Millenium hand and shrimp!
    1. Re:Summary is flat-out wrong. by mako1138 · · Score: 4, Informative

      http://en.wikipedia.org/wiki/National_High_Magnetic_Field_Laboratory

      There's a 60T pulsed magnet at LANL. "Power comes from a pulsed power infrastructure which includes a 1.43 gigawatt motor generator and five 64 megawatt power supplies. The 1200-ton motor generator sits on a 4800-short ton (4350 t) inertia block which rests on 60 springs to minimize earth tremors."

      And they're building a 100T edition.

  5. Re:Another limit? by who+knows+my+name · · Score: 5, Informative

    optical fibres are amorphous, and definitely not ductile. However they are used for miles of cable. You can bend them a few degrees, which is all you really need. I suppose a superconducting ceramic would be worse, but you could still get a significant bend over a kilometre. I think the main barrier is still temperature, I think I read the best we have so far is just above the boiling point of Nitrogen, ~80K

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  6. Re:Another limit? by compro01 · · Score: 4, Informative

    Actually, they're currently working on using a LN-cooled superconductor link in NYC to link some substations in Manhattan. It would replace an oil-cooled copper link. They're expecting to have it running in 2010.

    link

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  7. reality check by Anonymous Coward · · Score: 5, Informative

    I am a condensed-matter physicist but not a superconductor specialist.

    The article does not say that the material is immune to magnetism.

    The data relevant to this discussion is presented in Fig. 6 in the paper, which is a plot of the upper critical field (the maximum field the material can support and still be superconducting) versus temperature. Look at the traces marked with square markers.

    Notice that these curves do not diverge to infinity as the summary would have you believe.

    Granted, values in the 50's of Tesla seem pretty big, considering that the ambient magnetic field on Earth is about 0.5 Tesla. But note that other superconductors have critical fields in this same range. The famous high-Tc superconductor YBCO has a critical field of 135 Tesla (ref: http://www.springerlink.com/content/j0128jt30843362u/)

    Compared to elemental superconductors, whose critical fields are around 1 Tesla or less, this material does indeed support a lot more magnetic field. But it certainly isn't "immune to magnetism"

    1. Re:reality check by necama · · Score: 5, Informative

      Granted, values in the 50's of Tesla seem pretty big, considering that the ambient magnetic field on Earth is about 0.5 Tesla. I'm just quibbling on units -- the Earth's magnetic field is 0.5 gauss, or, 50 microTesla. Other than that, I agree with your comment 100%.

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      Just another condensed matter physicist.
  8. Re:Another limit? by negRo_slim · · Score: 4, Informative

    Aye.. the highest temperature superconductor is mercury thallium barium calcium copper oxide (Hg12Tl3Ba30Ca30Cu45O125) at 138 K.

    --
    On the Oregon Cost born and raised, On the beach is where I spent most of my days
  9. Re:Another limit? by caffeinated_bunsen · · Score: 5, Informative

    As I understand it, they embed the superconducting material in a soft, non-superconducting metal like silver. There's a proximity effect at boundaries between superconductors and normal metals which allows the superconducting state to extent a short distance into the normal metal -- think of it as the Cooper pairs leaving the superconductor and taking a bit of time to notice that they're in a normal metal and split into single electrons. If the layers of normal metal between the superconducting grains are thin enough, then the supercurrent can run from one grain to the next, through the normal metal, without experiencing resistance.

    The ductility of the metal allows some flexibility and tolerance for thermal expansion, as well as providing a low resistance at high temperatures. That's useful because the ceramic materials have rather high resistance when they're not superconducting, which means that if a small segment of wire warmed up above the transition temperature, its suddenly high resistance and the large current flowing through it would cause it to heat up extremely rapidly. The silver provides a secondary current path, so the wire's likely to heat up slowly enough to turn the power off before the wire melts.

    --

    Bugrit! Millenium hand and shrimp!
  10. Re:Another limit? by flux+pinner · · Score: 5, Informative

    There are a variety of techniques (depending on the application) that manufacturers use to overcome the inherent brittle nature of most superconductors.

    For magnet windings, the preferred technique is to fabricate the wire from ductile precursors, draw to final size, wind the coil, and then perform a heat treatment to react the precursors and form the brittle, superconducting phase. This, for example, will be the technique used when brittle Nb3Sn is used in the magnets for the ITER project.

    A related solution is to grind the brittle superconductor into powder, insert it into a tube, and use the natural rolling and sliding action of the particles to draw the material into a fine wire that can be subsequently wound into a magnet, with a heat treatment employed to sinter the powder particles back together to form a continuous superconducting path. This is a common technique for MgB2 superconductors.

    For non-magnet applications (like power transmission), the preferred technique is to make a tape (e.g. YBCO) that has only a very thin layer of brittle superconductor. Just like a glass fiber, this very thin layer has a very small bending moment in one direction, and so can be spooled (and unspooled) in this direction, allowing you to manage long lengths.

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    Reasoning is never, like poetry, judged from the outside at all.
  11. Re:Internal Resistance by jhantin · · Score: 3, Informative

    Is there something that happens at 0F? Ice and salt at 1 atm will stabilize at 0 degrees Fahrenheit; the zero point was originally defined in terms of ice and ammonium chloride.
    --
    ...when you're writing a game...tweak the difficulty of "Easy" to something [your mother] can cope with. -- onion2k
  12. Re:Internal Resistance by TheLink · · Score: 3, Informative

    "And I can never remember how to do it"

    Use Google.

    e.g. http://www.google.com/search?hl=en&q=0F+in+C

    It does other unit conversions kph to mph, US gallon to UK gallons, currency conversion.

    And also stuff like how long it takes to transfer 700MB over a 512Kbps link:

    http://www.google.com/search?hl=en&q=700+MB%2F+512kbps
    http://www.google.com/search?hl=en&q=700+MB%2F+512Kbps+in+seconds

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