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Science

Entanglement Makes Quantum Particles Measurably Heavier, Says Quantum Theorist 109

KentuckyFC writes: Physicists have long hoped to unify the two great theories of the 20th century: general relativity and quantum mechanics. And yet a workable theory of quantum gravity is as far away as ever. Now one theorist has discovered that the uniquely quantum property of entanglement does indeed influence a gravitational field and this could pave the way for the first experimental observation of a quantum gravity phenomenon. The discovery is based on the long-known quantum phenomenon in which a single particle can be in two places at the same time. These locations then become entangled — in other words they share the same quantum existence. While formulating this phenomenon within the framework of general relativity, the physicist showed that if the entanglement is tuned in a precise way, it should influence the local gravitational field. In other words, the particle should seem heavier. The effect for a single electron-sized particle is tiny — about one part in 10^37. But it may be possible to magnify the effect using heavier particles, ultrarelativistic particles or even several particles that are already entangled.
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Entanglement Makes Quantum Particles Measurably Heavier, Says Quantum Theorist

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  • by Cassini2 ( 956052 ) on Tuesday January 06, 2015 @05:50PM (#48750315)

    We only need to measure the mass of a 9.10938291 × 10^-31 kilogram particle accurate to 1 part in 10^-37. Alternatively, we can speed the electron up to 0.999c so it weighs more, then entangle it, and then measure it's mass to 1 part in 10^-37, with less than 5 sigma of measurement error.

    Either way, I should have it done by lunch time.

    • [...]Either way, I should have it done by lunch time.

      I see you've read the article, so can you explain something for me?

      I'm told that photons gain energy when falling into a black hole. Suppose you have two entangled photons and one goes off and gets captured by a black hole.

      Based on the article, would there be any noticeable effect on the other entangled photon?

    • by radtea ( 464814 ) on Tuesday January 06, 2015 @08:06PM (#48751101)

      Either way, I should have it done by lunch time.

      Or we could spend some time coming up with additional consequences that might allow indirect tests. For example, does this effect have any consequences for the spectrum of Hawking radiation (just to consider one area were entangled pairs and high gravitational fields are involved)?

      How about the structure of the very early universe?

      Or are there ridiculously subtle interferometric effects that might allow the detection of the phenomenon? Or other quantum effects?

      Consider the Mossbauer Effect as an example of measuring stupidly small energy splittings so many orders of magnitude below any reasonable detector resolution that no doubt some smug bastard made fun of the people doing the hard work of calculating them "because no one will ever be able to measure that!"

      • by smaddox ( 928261 )

        Mod parent up.

        Also, perhaps further development of the theory could hint at methods of unification of QM with GR.

      • Sure, and consider that we do not yet have direct experimental confirmation that antiparticles fall down, instead of up. There's a reason for that, and it is 30 orders of magnitude.

        The antiparticle experiment actually might be doable. And it is the thing that is a mere 37 orders of magnitude short of measuring the difference in weight of entangled quantum antiparticles.

        So yes, you are right, one cannot be certain that there is no supremely clever way to measure Planck-length scale phenomena without using

    • You saved me from having to reply. I do not think that this "measurably heavier" means what you think it means (or rather, they think that it means), to quote Inigo Montoya. Let me 'splain. No, there is too much, let me sum up. In addition to the fact (as you have so ably pointed out) that we will never, in the future course of the universe, be able to measure the effect predicted, it is a theoretical prediction based on assumptions in a particular circumstance. If the assumptions turn out not to be co

      • I'll raise you this quote: "You'd like to think that, wouldn't you?!" yet on the actual arXiv site they do indeed say "Our results suggest that there is a form of entanglement that has a weight." It's actually the third word of the paper. And here, weight IS the correct term, as it is the measurement of the pull of gravity on an object. That's the whole point of the paper...current theory is quantum entanglement doesn't interact with gravity but these guys say in certain instances this might be incorrect.
        • So you're/they're saying mass-energy in any form doesn't have a "weight"? Einstein was even wronger? Rearrangements at constant mass-energy can have different weight? At the Planck scale you can say pretty much anything you like and not have much chance of your words being falsified, and while I'm not a falsificationist and agree that a consistent hypothesis can have meaning even if it can't be verified or falsified, this falls into the same scientific category that magnetic monopoles do, only tens of or

  • It's true (Score:5, Funny)

    by Gliscameria ( 2759171 ) on Tuesday January 06, 2015 @06:00PM (#48750393)
    Yo mama's so fat her wave function collapses into multiple eigenstates.
    • by Anonymous Coward

      I noticed how fat yo mamma is when I got entangled with her last night.

  • So what is going to be the Next Big Thing?

    What is the next Theory of Relativity waiting to be solved and what will be the game changing technology made possible by it?

    • by Gravis Zero ( 934156 ) on Tuesday January 06, 2015 @06:28PM (#48750565)

      not to spoil it for you but it's time travel. i'll be making my announcement in 2044 and personally demonstrate that you can travel 5 minutes back in time. needless to say, i forgot to carry the one.

      • by Anonymous Coward

        Time travelling works fine. To prove it, I will travel back to when this article was accepted on slashdot and be the first poster. Be warned, time travelling makes me cranky and homophobic.

  • Not "does indeed" (Score:4, Insightful)

    by harryjohnston ( 1118069 ) <harry.maurice.johnston@gmail.com> on Tuesday January 06, 2015 @06:21PM (#48750529) Homepage

    That's a theoretical analysis, not an experimental measurement, and is likely to be particularly dubious since we don't have a working theory for quantized general relativity yet. Interesting, but the phrase "does indeed" in the summary is a significant overstatement.

  • This sounds a lot like Penrose's proposal for wavefunction collapse caused by gravitational disturbance caused by particles being in a superposition of two locations...

  • Seeing as you are talking about a change in mass that is 34 orders of magnitude smaller than the Planck constant

    h/2 > (delta MV)(Delta x)

    (6.62606957 × 10-34 m2 kg / s)/2 > (Delta (M)*V)(Delta x)

    delta M = 9.10938215kg×(10^-31)/ 10^37
    or = 9.10938215kg×(10^-68)

    We are looking at some pretty big uncertainty about where the particle is and how fast it's moving.

  • FTL communications? (Score:4, Interesting)

    by Ken_g6 ( 775014 ) on Tuesday January 06, 2015 @06:41PM (#48750639)

    Given that two particles can emitted by a single source entangled, sent a long distance apart, and remain entangled,
    And that if one particle becomes disentangled the other particle instantaneously becomes disentangled,
    If we can measure the entanglement of a particle by its mass,
    Then we can communicate faster than light.

    But the no-communication theorem [wikipedia.org] states that, during measurement of an entangled quantum state, it is not possible for one observer, by making a measurement of a subsystem of the total state, to communicate information to another observer.

    So I think this means that either the no-communication theorem is wrong, or the change in mass of an entangled particle cannot be measured.

    • by radtea ( 464814 ) on Tuesday January 06, 2015 @08:01PM (#48751079)

      So I think this means that either the no-communication theorem is wrong, or the change in mass of an entangled particle cannot be measured.

      That's an interesting point, but on my reading of the paper (which was pretty cursory, admittedly) the extra mass term comes from the joint wavefunction, which means both particles would have to be measured. It looks like the pair has greater mass, not the individual particles.

      This makes sense because insofar as they are entangled it doesn't even make sense to talk about the individual particles. Furthermore, if one were to measure either of the particles individually, that would break the entanglement and the extra mass term would fall to zero.

      Thing of the highly idealized experiment of two sources on a balance beam, one that emits pairs of non-entangled particles, one that emits pairs of entangled particles. The theory says that the balance will tip toward the side of the entangled pairs, but it does not follow from this that measurements on any of the individual particles will reveal increased mass.

    • Sorry but the no-communication theorem seems BS. If you are able to obtain the polarization of the photon and you are also able to force this photon in a given polarization, and the photon is in an entangled state (existing in two places at once), so I do not see what would prevent the transmission of information using this effect and the theorem fails to explain what would be a good reason for this communication be impossible.
  • It seems to me that one way to state this information is that mass can be a variable according to circumstances. And that screws the pooch. Are we entering an era in which every term in an equation is a variable? Can mathematics tolerate multiple variables within an equation? And if so to what degree can variables be the elememts of an equation and yield any useful solutions?
  • wouldn't it be cool (Score:5, Informative)

    by slew ( 2918 ) on Tuesday January 06, 2015 @06:59PM (#48750757)

    FWIW, it appears from the paper that this extra "mass" is an artifact of analyzing entangled particles in a linearized gravity [wikipedia.org] framework and observing a stress-energy tensor term that seems to appear higher for entangled particles and radiated away as particles move to decoherence. This perhaps might be considered the mass of the entanglement.

    On the other hand, wouldn't it be cool if the reason for the observed equivalency of gravitational mass and inertial mass was somehow related to quantum entanglement? (yes I know this is unrelated to this phenomena, but still)...

    • by PopeRatzo ( 965947 ) on Tuesday January 06, 2015 @07:11PM (#48750839) Journal

      it appears from the paper that this extra "mass" is an artifact of analyzing entangled particles in a linearized gravity [wikipedia.org] framework and observing a stress-energy tensor term that seems to appear higher for entangled particles and radiated away as particles move to decoherence.

      Right? I was just gonna say that.

    • by mbone ( 558574 )

      Is it really a motional term (i.e., due to a higher level of quantum jitter)?

    • Dude that would be so cool!

    • by drolli ( 522659 )

      I looked at the paper and i have the feeling that they misuse the term "entangled". At least their definition of the density operator seems dodgy. If they would not say it's entangled i would call it a superposition state of a single particle.

      Which, in terms of the density matrix is not so different. But we experimentalists usually require two particles with multiple states to use the word "entanglement".

      Moreover, since they are comparing a mixed state, i would find it particularly interesting if there is

  • by mbone ( 558574 ) on Tuesday January 06, 2015 @07:10PM (#48750837)

    Entanglement Makes Quantum Particles Measurably Heavier

    One part in 10^37 is not measurably heavier. No measurement in science has anything like 37 significant figures*.

    *No, the cosmological constant does not count, as it was not measured from quantum principles, but from cosmological ones.

  • I'm not fat, I'm quantum entangled!
  • by sexconker ( 1179573 ) on Tuesday January 06, 2015 @08:18PM (#48751139)

    The discovery is based on the long-known quantum phenomenon in which a single particle can be in two places at the same time.

    Wrooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooong.

    • The discovery is based on the long-known quantum phenomenon in which a single particle can be in two places at the same time.

      Wrooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooong.

      Right. The long-known phenomenon is that a single particle can have two velocities at the same time. Sheesh.

  • by Richy_T ( 111409 ) on Tuesday January 06, 2015 @10:55PM (#48751975) Homepage

    Leon's getting larger.

  • Didn't RTFA, but still wondering: does this mean quantum encryption can be beaten by adding a "weight scale" to the transmission link?

  • I'm just really quantumly entangled.

  • I don't buy it.

    It takes about 8 minutes for the gravity from the sun to reach the earth, but quantum phenomena would travel instantaneously.

    Different things.

    That's a little anecdotal, but all truth is on some level.

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