excreationist

It might take me a long time to get my hands on one of them.... (I try to avoid paying for books since they are expensive)

Lykil

I understand that it is difficult to explain here, but still, let me just summarize my problems: Let’s say you have two entangled particles, that you move to a great distance of each other. According to the EPR exp. (if I haven’t misunderstood it completely) it should be possible to measure only one of them, and instantly deduce what the other particle would be, since they always come in pairs, and the one particle is the opposite of the one measured. I believe that the EPR showed very clearly (assuming the ‘fuzzy state’ is a fact) that there was instantanious communication between the particles. Since this communication is directly related to our measurement of the particles, why don’t we get the crucial data, that allows for the deduction?

</strong>

This seems to support faster-than-light (FTL) communication. The explanation I’ve been given though is that the particles first have to travel the distance that they are separated, at sub-light speed, and therefore the communication isn’t really faster-than-light, it’s just put on hold until after the particles have arrived/been measured. Vaguely similar to a closed letter being opened at a certain point. No one would say that letters communicate faster-than-light (especially not where I live), even though the information is hidden from the outside world before the letter is ‘measured.’

As for a sensible interpretation of the FTL communication, does anyone have any comments on the idea of a different dimension (a fifth or something) that ties the particles together so that the communication isn’t really FTL, but only the distance is zero through this strange dimension otherwise invisible to us? I don’t know how much of this is science and how much is just this guy trying to fool me into thinking he knows a lot

</strong>

Exactly. If we compare the particles in the tunnel to – say – billiard balls, all that seems to happen is the device used to measure the particles deflecting them, and thus changing the results, rather than instantiating (?) them.

As for books, I can’t afford to buy them right now, so if anyone has an interesting URL or knows a link to a great website, please: POST IT HERE!

Regards
Mandark

Ipecac

This is simply not true. It has been shown that <a href="http://www.compu-web.com/nimtz.htm" target="_blank">using quantum tunneling you can transmit data faster than light. </a>


Fixed link, it works now.

[ March 03, 2002: Message edited by: Ipecac ]</p>

Malaclypse the Younger

The link is defective, so I'm unable to evaluate the claim.

Much depends on the definition of "information". It is certainly true that quantum events are nonlocally correlated, which requires that the quanta have "information" about each others' states.

However, AFAIK, it is known that according to our present understanding of QM one cannot use quantum entanglement to nonlocally transmit "information" in the sense of a message of the traditional sort, such as a string of characters.

[ March 03, 2002: Message edited by: Malaclypse the Younger ]</p>

Ipecac

Not necessarily. Let's say you have two pair of entangled particles, pairs AA and BB. I have one half of the pair AB and you have the other, AB. Let's say we take our two particles and separate them by a light week. If I manipulate one particle(A) so that its state changes in a predermined way when you observe this state change(on your A) you do the same thing on the other half of the other pair(your B). I should see the same state on my other particles when I observe it(on my B). It theoretically should take no longer than for me to observe the change and initiate the same change on the other particle. You could theoretically reduce this experiement to a couple of light seconds in distance to test the theory. This shouldn't be impossible to test now that we have created entangled molecules.

Malaclypse the Younger

First of all, we need to be rigorous about what we mean by "manipulating" an entangled particle.

To "manipulate" an entangled particle means to perform a "measurement" on that particle which will collapse a mixed state into an eigenstate (a particular state).

According to QM, once you perform a measurement on one of two entangled particles and determine its eigenstate, the other particle will be in the correlated eigenstate.

For instance let us assume that we are measuring the vertical polarization of two correlated photons.

Before the measurement, each photon is in a mixture of possible polarization states. It's state vector is sqrt (2) * up + sqrt (2) * down; it's in a mixture of the up and down state.

When we measure one photon, we reduce this mixture of states to a definite state, either up or down; it's state vector becomes either 1 * up + 0 * down or 0 * up + 1 * down (the "eigen" in "eigenstate" refers to the "1").

Since the photons are correlated, when I determine the eigenstate of one photon, I know that the eigenstate of the correlated photon is the opposite. So I know that if I measure an up state, my partner will measure a down state and vice versa.

However, since I don't know what state I will get when measuring a photon, I can't use the information I receive to transmit a message. It is important to note that I can't make the photon be in either an up state or a down state; I can merely transform the mixed state to some random eigenstate.

So what both my partner and I see when measuring the states of photons are merely a random collection of up and down states. It is only when we transmit our various measurements to each other locally (speed-of-light) that we can detect the correlation. Until we do so, we merely have a random collection of up/down states with no way to assign meaning to the results.

[ March 03, 2002: Message edited by: Malaclypse the Younger ]</p>

Ipecac

We can't make a photon be in a particular state today. This does not mean we will never be able to do it. Also, now that we have been successful in creating entangled molecules it might be easier to manipulate these objects. Certainly we can manipulate the states of a molecule.

Malaclypse the Younger

True indeed.

IIRC, Nick Herbert proved that our current formulation of QM precludes superlumunal information transfer (although I haven't seen the proof). If we had evidence that we could directly manipulate the quantum state of a photon, we would have to substantively adjust our current formulation of QM--which is not impossible.

However, based on today's understanding of QM, there is no rational justification for the belief that superluminal information transfer is possible.

Lykil

Thanks for clearing that up. I think a lot of the misunderstanding about communicating faster than light stems from not understanding this bit clearly enough, and also from not knowing exactly what you mean by 'communication.' At least that was my biggest problem.

p.

Jesse

Something I posted on QM and the EPR experiment on another thread a while ago:

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Although people usually focus on indeterminacy when discussing the mysteries of quantum mechanics, the real mystery is that QM poses a lot of problems for a realist view of reality, i.e. one where the properties of the world exist independently of our measurement. This is most obvious in the EPR experiments where properties of entangled particles are measured at different locations. What we find is that there are regular correlations between measurements made on particle A and measurements made on particle B which are inexplicable if we picture the particles as classical objects with definite properties that cannot communicate faster than light--this is what Einstein called "spooky action at a distance."

It is sometimes imagined that the uncertainty principle, which prevents us from knowing simultaneously the value of two noncommuting variables (like position and momentum), is just a limitation on measurement; maybe the particle has a definite position and momentum at any given time, but each time we try to measure the position it changes the particle's momentum in a random way, and each time we measure the particle's position it offsets the momentum. However, the EPR experiment shows it is much worse than that. The correlations between entangled particles are such that they cannot be explained by any picture of the world in which the particles have definite values for each noncommuting variable at every time, unless the particles can somehow communicate instantaneously so as soon as you measure one the other "knows" which property you measured and adjusts its own properties. This is the result known as "Bell's Theorem," which says that no local theory of hidden variables can explain the results of the EPR experiment.

In Huw Price's Time's Arrow and Archimedes' Point he offers a little story to help us see what's so strange about the EPR results:

This is the problem posed by the EPR experiment in a nutshell. As the great physicist Richard Feynman said, "Nobody understands quantum mechanics…do not keep saying to yourself, if you can possibly avoid it, 'But how can it be like that?' because you will go 'down the drain' into a blind alley from which nobody has yet escaped. Nobody knows how it can be like that." The weirdness of QM, and the difficulty with imagining "how can it be like than" in a way consistent with the view that reality exists before we observe it, extends to other famous experiments and thought-experiments, like the <a href="http://www.time-travel.com/twoholes.htm" target="_blank">Double-slit experiment</a> and the Schroedinger’s Cat experiment. (is the cat ‘really’ alive or dead before it is measured?) But the EPR experiment shows most clearly what the basic problem here is for a realist.

A number of different "interpretations" of quantum-mechanical weirdness have emerged over the years, with none yielding any new physical predictions (and thus being experimentally indistinguishable) but each offering a different way to conceptualize what’s "really" going on in these sorts of experiments. <a href="http://www.tcm.phy.cam.ac.uk/~mdt26/qmint.html" target="_blank">Here</a> is a page which gives some good links on these various interpretations, and I’ll attempt my own summary here:

1. The Copenhagen Interpretation

Basically, the Copenhagen interpretation says that we shouldn’t worry about how what’s really going on in the first place—science can only deal with correlating and predicting the results of various measurements, but it can’t tell us anything about what goes on when we’re not looking. This is basically a logical positivist perspective, and it was preferred by Bohr.

2. "Objective Collapse" interpretation

Here the wave-particle duality is taken literally—the world exists as a wavelike potential when it’s not being observed, but somehow measurements periodically "collapse" the wavefunction into a definite state. Some versions of this suppose that it’s consciousness that does the collapsing, others suppose that an entangled system collapses once it reaches a certain limit in mass. Unlike the other interpretations, these might actually be expected to yield different predictions than orthodox QM—so far, there’s no evidence for anything like this though.

3. The Bohm-de Broglie interpretation

Bell’s theorem shows that no local hidden variable theory can explain the results of the EPR experiment, but that leaves open the possibility of a nonlocal hidden variables theory where particles can communicate faster than light. This is the route taken by Bohm and de Broglie’s interpretation. In the Ypiarian story, this would be like the twins having a psychic link which allows one to know what question the other was asked, and adjust his own answer accordingly.

4. Transactional interpretation

The EPR experiment can also be explained if you assume the future can affect the past, so that the particle’s original properties are affected by the measurements that will be made on them later, once they are separated. In the Ypiarian story, this would mean that the twin’s choices to commit or not commit various crimes would be affected by which questions they would be asked much later when they’re interrogated. This isn’t as strange as it sounds, since all the laws of physics we currently know of are time-symmetric (they look the same forwards as they do backwards) and apparently the apparent "arrow of time" emerges solely from statistical mechanics, perhaps because the universe started off in a very low-entropy state. Huw Price’s book Time’s Arrow and Archimedes’ Point, which I quoted from above, deals with this problem; not surprisingly, he favors a version of this interpretation.

5. The Many-Worlds interpretation.

This interpretation takes the mathematical formalism of QM literally and proposes that the wavefunction is all there is. This means that when I measure the state of a particle that’s in superposition, instead of "collapsing" it into a definite state, I just become entangled with it and enter into a superposition myself; basically, I "split" into two versions of myself, one of whom observes one state and another of whom observes another. In popular accounts this is sometimes explained in terms of the entire universe splitting into parallel histories all the time, but it’s a bit more subtle than that, since different "worlds" can interfere with each other and cannot be viewed as totally "parallel,’ although thermodynamics may explain the appearance of splitting through a phenomenon called <a href="http://ii-f.ws/ubb/ultimatebb.php?ubb=get_topic&f=10&t=000355" target="_blank">decoherence</a>. For technical reasons this interpretation preserves locality (see question 12 of the <a href="http://www.hedweb.com/everett/everett.htm#local" target="_blank">Everett FAQ</a>), and it’s also 100% deterministic to boot (although it suggests an odd kind of subjective indeterminacy in which my first-person experience randomly chooses which split copy to become—hence a variation of this interpretation is the <a href="http://www.poco.phy.cam.ac.uk/~mjd1014/" target="_blank">many-minds interpretation</a> which deals with this issue a little more explicitly). This interpretation usually seen as theoretically the most elegant, and is often implicitly assumed in quantum cosmology, although physicists are often agnostic about whether other worlds/histories are actually "real." Many-worlds also helps make sense of quantum computation, which can be understood elegantly in terms of the computer performing different computations in different worlds and then combining the results through interference:
<a href="http://www.doc.ic.ac.uk/~ids/quantum_computing.html" target="_blank">www.doc.ic.ac.uk/~ids/quantum_computing.html</a>
<a href="http://www.herwig-huener.de/quantum.html" target="_blank">www.herwig-huener.de/quantum.html</a>
<a href="http://www.qubit.org/" target="_blank">www.qubit.org/</a>
<a href="http://www.qubit.org/people/david/Articles/Frontiers.html" target="_blank">www.qubit.org/people/david/Articles/Frontiers.html</a>
<a href="http://www.innerx.net/personal/tsmith/ManyWorlds.html#expmw" target="_blank">www.innerx.net/personal/tsmith/ManyWorlds.html#expmw</a>

So, those are the various interpretations…as I said, the main problem is that none of them really gives any new testable predictions, which is a bit unsatisfying. There’s some good reason to think that a theory of quantum gravity would transform our understanding of QM somewhat, so perhaps such a theory will depend on a modified version of one of these interpretations that is testable in some way. In any case, Bell’s inequality shows definitively than no classical, realist picture of the world can explain the EPR results, so whatever the truth turns out be, it’s guaranteed to violate our cherished assumptions in one way or another (faster-than light signalling, the future affecting the past, parallel universes…take your pick!)

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