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Physicists Observe the Majorana Fermion, Which Is Its Own Antiparticle

Posted by Soulskill on from the stuff-that-antimatters dept.

Charliemopps writes: "For the first time Princeton University scientists have observed a Majorana fermion, a long-predicted but never observed exotic particle that acts as both matter and anti-matter (abstract). "The setup they created starts with an ultrapure crystal of lead, whose atoms naturally line up in alternating rows that leave atomically thin ridges on the crystal's surface. The researchers then deposited pure iron into one of these ridges to create a wire that is just one atom wide and about three atoms thick. ...[Next, they] placed the lead and the embedded iron wire under the scanning-tunneling microscope and cooled the system to -272 degrees Celsius, just a degree above absolute zero. After about two years of painstaking work, they confirmed that superconductivity in the iron wire matched the conditions required for Majorana fermion to be created in their material." The particle is surprisingly stable. Being in both states at once seems to make it interact very weakly with its surrounding material. This could also be a major step towards quantum computing.

11 of 99 comments (clear)

  1. Well that's random by bhcompy · · Score: 5, Funny

    This could also be a major step towards quantum computing.

    Why is that just thrown in there? It seems kind of random.
    "Pizza Hut has created a bacon, cheese, AND sausage stuffed crust pizza! This amazing pizza is very delicious. This could also be a major step towards quantum computing."

    1. Re:Well that's random by Jaime2 · · Score: 5, Informative

      From the article: "Importantly, Kitaev also outlined how such a particle could be harnessed as a qubit, the basis of a quantum computer, which added significant impetus to the search."

    2. Re:Well that's random by countach44 · · Score: 5, Informative

      I apologize that I don't have time to construct a proper reply, but this article gives a nice explanation of how majorana fermions can be used to make qubits (hopefully it's not paywalled, but I'm on a university network so it's hard for me to tell): http://www.nature.com/nphys/jo...

    3. Re:Well that's random by Hartree · · Score: 4, Informative

      Not so random. Maybe a long ways distant. (i.e. It's vaporware, but give us more money.)

      One of the problems of current quantum computing qubits is they are easily upset by thermal and other noise from their surroundings.

      There are certain systems that involve Majorana fermions that have been theorized to be what are called topologically protected states. These would be largely immune to noise in a way similar to how electron pairs in a superconductor are immune to the normal energy losses that cause resistance in a wire.

      A problem with this, is, we hadn't really shown that Majorana fermions actually existed.

      This is a hot area of solid state physics research. Note that these are not particles in the usual sense, but things that behave like particles (like electron pairs in a superconductor behave kinda sorta like single particles). They fall under the general term of quasiparticles.

  2. Re:What is there to say? by turkeydance · · Score: 4, Funny

    finally, some nerd news.

  3. The summary is missleading by angel'o'sphere · · Score: 4, Insightful

    Perhaps it would have been much easier and much more accurate to copy/paste simply the original MIT abstract of the article.

    The 'discovered' Majorana Fermion is a quasiparticle, created at the boundary edges of two superconductors. http://en.wikipedia.org/wiki/Q...

    In this case iron and lead, so there is actually no 'new particle' discovered but more or less only a 'quantum point' created by weird behaving electrons ...

    And this all together is light years away from anything useful regarding quantum computing (IMHO :) )

    --
    Cost free eBook I read (by iBook/Kobo/Amazon/ObookO/Gutenberg etc.): "The Green Odyssey" by Philip Jose Farmer.
  4. Fermion that is its own antiparticle by blueg3 · · Score: 5, Informative

    The summary (and the article!) imply that it is rare and strange for a particle to be its own antiparticle. This is not the case. Plenty of boson and mesons are their own antiparticles: photons, gluons, pions, etc. This isn't a particularly weird situation.

    However, fermions are another story. Fermions and bosons are the two kinds of fundamental particles. They behave very differently. While there are bosons that are their own antiparticle, there are no known fermions that have this property. All the fermions we know of are Dirac-type. It's been long postulated that there could be Majorana-type fermions, which, among other things, are their own antiparticles.

    It's interesting, but not quite as crazy as implied.

    1. Re:Fermion that is its own antiparticle by nine-times · · Score: 4, Interesting

      Ok, so if you know this stuff, what does it mean for a particle to be its own antiparticle? Does that mean if it comes into contact with another such particle, they're both annihilated? Does that mean that they're neutral to matter and anti-matter, or do they still somehow fall into one of those categories?

    2. Re:Fermion that is its own antiparticle by blueg3 · · Score: 4, Informative

      That's hard to answer for a few reasons. I'm not a particle physicist, the subject is kind of complicated, and most people start off ill-informed (sorry!).

      Antiparticles are not particularly weird and particle-antiparticle interactions are, in particular, not some kind of physical witchcraft. I always have disliked that it's called annihilation. At the subatomic level, particle interactions are common and they generally involve the "creation" and "destruction" of particles. For example, maybe a neutron decays into a proton, an electron, and an electron antineutrino (by way of one of its down quarks changing into an up quark). Particle interactions are all sort of a shuffling of energy between the different flavors of bundles of energy we call particles. Lots of different physical quantities, like charge, are conserved, limiting what interactions can happen.

      In the interest of simplicity, a lot of what I'll say next is slightly wrong.

      Antiparticles aren't particularly weird. Particles all have a set of physical properties. It turns out that for each particle, there is another particle that is basically exactly the same, except all these physical properties are opposite. So an electron has charge -1 and an antielectron (positron) has charge +1. In fact, if you look at a legal particle interaction and replace all of the particles with their antiparticles, it's still a legal particle interaction.

      An implication of this is that if a particle and its antiparticle interact (not a particle and *any* antiparticle, but *its* antiparticle), the net total for any of their conserved quantities (like charge) is zero. That means the major legal interaction is that the two particles are destroy and produce photons. While photons are particles, we tend to think of them as just energy, so the particle-antiparticle interaction is an "annihilation": two particles go in, energy and zero particles come out.

      The "its antiparticle" bit is important. You don't see a lot of antielectrons because a free antielectron would easily encounter an electron and annihilate. But there are plenty of antineutrinos because they interact weakly with the rest of the world. An antineutrino interacting with, say, a proton does not cause annihilation. Even an antielectron interacting with, say, a proton doesn't do anything special.

      Oh, also, it turns out that, at least for the "normal matter" particles like electrons and protons, the universe seems to contain pretty much only the normal-matter particles and (relatively) no antiparticles. There doesn't seem to be any reason, in physics, for one to be preferred over the other. (It's just that in one region of space, you couldn't have a mixture and also have stable matter.) So that's weird.

      This is all a long-winded way of getting to the answer that particles that are their own antiparticles aren't particularly exciting. They all have the property that conserved quantities (at least, those that are negated in antiparticles) are zero. So they all naturally have annihilation interactions: when two collide, they can annihilate and form protons. But the annihilation interaction isn't particularly dramatic or weird, it just sounds interesting. The particles all probably also have interactions with all sorts of other types of particles, too, and it really comes down to what particle it happens to collide with first. Maybe a photon and an antineutrino interact with a proton and form a neutron.

      Most of the particles that are their own antiparticles are relatively neutral to normal matter (and consequently, also to normal antimatter). But they're all a very different kind of particle from normal matter. They're things like force-carriers (photons) and muons, and they interact with electrons and protons differently from how electrons and protons interact with each other.

      For some real fun, look up Feynman diagrams, a neat way of writing down different legal particle interactions. One axis is space (in one dimension) and one axis is time. Now, any 90-degree rotation of a legal interaction is still a legal interaction.

  5. Quick explanation by Okian+Warrior · · Score: 5, Informative

    A Majorana particle is it's own antiparticle; such as, for example, a photon.

    Most fermions have different antiparticles from themselves: Protons are notably different from anti-protons, electrons are different from positrons, and so on. The one exception is the neutrino, for which the question is not yet settled.

    If the neutrino is its own antiparticle, we should see double-beta-decay events. A beta decay emits a neutrino, so if two happen simultaneously the neutrinos should annihilate if they are their own antiparticle. (Wikipedia link)

    As yet no experiment has seen double-beta-decay, so it's likely that the neutrino has a distinct anti-neutrino - an intriguing prospect.

    The article referenced in the post does not identify the fermion involved, so one can only assume that it's a "quasi particle", which is a type of vibration. Essentially a phonon (sound wave) with fermion-like properties.

  6. NOT a Real Majorana Fermion by Roger+W+Moore · · Score: 4, Interesting

    It's sure a particle alright.

    Not it is not. It is really just a simulation of a particle. All they have done is create a system which behaves like we think a majorana fermion should behave. They have emphatically NOT created a new fundamental particle. What they have done is hype up the interesting physics they have done to make it look like they are doing particle physics which they are not.

    Don't get me wrong: this is definitely an interesting result but it is unnecessary, and rather deceptive, to present it as particle physics when it isn't. Such experiments are very interesting and worthwhile because they may improve our understanding of how a majorana particle behaves. However if we found an inexplicable deviation between the way that this "simulated particle" behaves and how a theoretical majorana fermion is expected to behave after 'debugging' we would put it down to them not simulating the particle correctly and we would not be rewriting the fundamental laws of physics.