Beginner's Guide to Quantum Entanglement

No Fortune writes "Einstein called it 'Spooky action at a distance.' This article describes, in scientific layman's terms, how spooky action is created." From the article: "Normally the photons exit the crystal such that one is aligned in a horizontally (H) polarized light cone, the other aligned vertically (V). By adjusting the experiment, the horizontal and vertical light cones can be made to overlap. Even though the polarization of the individual photons is unknown, the nature of quantum mechanics demands they differ."

Jesus Zonk...

[grasshoppa]

...what the hell is the matter with you anyway?

Throwing that kind of physics at us on a Saturday evening when you *know* most of us are half drunk?

Bastard.

Re:Jesus Zonk...

[Private+Taco]

Perhaps Zonk is half drunk as well.

Re:Jesus Zonk...

[ZachPruckowski]

More to the point, it's 11:33 PM on a Saturday at UVA, and I'm reading about quantum stuff. I'm far worse than Zonk right now. :(

Re:Jesus Zonk...

[Deltaspectre]

You realize this is how most physics revelations come by, eh?

Re:Jesus Zonk...

[myth24601]

The ones that understand this stuff would never go out on a Saturday night... or Friday... or Monday... well, you get my point.

Re:Jesus Zonk...

[Helios1182]

Half drunk? Bah.

Re:Jesus Zonk...

[argontechnologies]

Half drunk my Arse... I'm fully drunk! Paid Darn good money for that hooch too.

Re:Jesus Zonk...

Aw, can't get up the energy to party after getting royally spanked 52-14 by Virginia Tech, can we?

Re:Jesus Zonk...

[mortong]

This is the best article I've read in a long time. Being drunk just means I was able to not think too hard about the philosophical repercussions and understand the point he was trying to make.

That being said, I've bookmarked it to read it again while I'm sober.

Re:Jesus Zonk...

[mortong]

Actually, I think it's the large amounts of alcohol that let's me understand it. Unfortunately, passionately trying to explain this stuff to the table full of drunks you're talking to on a Friday night causes nothing more than a few blank stares and a yawn in the pretty young woman who sat down next to you.

Re:Jesus Zonk...

[ZachPruckowski]

No, this is pretty typical for me. The football doesn't really bug me, because we own VT academically (by a mile), in athletics (when all sports are factored in, it's called the Commonwealth Challenge, and we usually win most of the head-to-head matchups, plus have more conference titles every year), and socially (better guy to girl ratio, plus our girls are hotter). Not to mention the original UVA campus is a UN historic site or something, and a bunch of other stuff I'm too lazy to mention.

Re:Jesus Zonk...

and the other haly fully-baked lol

Re:Jesus Zonk...

[Sir+Pallas]

My level of drunkeness was a wave function until I collapsed.

Re:Jesus Zonk...

[LinuxGeek]

Half drunk? Bah.

Yes, half drunk, one of the two possible quantum drunkeness states: half drunk and shitfaced.

Re:Jesus Zonk...

[rjmnz]

You're on the wrong side of the dateline.
It's Sunday PM here and I'm still half drunk, but I have to go to work in the morning!

Re:Jesus Zonk...

[VincenzoRomano]

Zonk is right! You left things half done and he's simply finishing the job!

Re:Jesus Zonk...

physics wtf i thought 'quantum entanglement' was a geek sitting at home on the weekend with the entire Quantum Leap series and watching it til their eyes bleed.

Re:Jesus Zonk...

Except that your campus is full of pretentious stuck up rich yuppie kids who think they're all that and a bag of chips. But thats just my personal observation. Personally, i like the style of VT, the people are great and usually laid back, as opposed to full of themselves. Of course, I myself went to the bastard step child of William and Mary, Christopher Newport UNiversity, so of course I am one of those kinds of people you look down your nose at.

Damppuss

Did you mean: fleabiteus ?

Zonk is Jesus?!

Lord help us... but anyway, you've got be half-drunk to even start getting quantum physics. Everyone knows that... well, they do when you ask, they didn't before you asked.

Re:Zonk is Jesus?!

[squidinkcalligraphy]

Well, fortune should have it that I have stumbled upon this article half (well, in fact, at least three-quarters) drunk, and as I read the article, I was thinking "gee, I'm half (well, in fact, at least three-quarters) drunk, and I _can_ understand this shit", so either, yes, Anonymous Coward, your postulate is correct, or this begginers guide is quite well written (perhaps better titled "Drunk's Guide to Quantum Entanglement").

What I do not understand, however (possibly due to my drunken state) is why it should be necessary that information flows between the two photons that are entangled. Could it not be that the parameters at the time of the split cause them to behave in particular fashions that will always complement each other? E.g. if I send a baseball in one direction spinning topwise, while at the same isntant sending a baseball in another direction spinning bottomwise, their spins will be opposite and continue to do so, without any interaction between the baseballs.

Again, sorry if the answer is blindingly obvious and I am merely oblivious.

Re:Zonk is Jesus?!

[EntropyEngine]

Even poor old Albert couldn't get his 'ead around any of it, so what chance do we stand?

Re:Zonk is Jesus?!

[ozbird]

Oh, he understood it alright - he just didn't like it: "God does not play dice."
Albert was a genius, but he was still human.

Re:Zonk is Jesus?!

[EntropyEngine]

He was reluctant to embrace the idea because of the fundamental collision of the quantum physics with his religious beliefs.

In later years, he dedicated precious time coming up with theories to explain quantum physics away, which was a shame...

Re:Zonk is Jesus?!

[jonadab]

> if I send a baseball in one direction spinning topwise, while at the same isntant sending a
> baseball in another direction spinning bottomwise, their spins will be opposite and continue
> to do so, without any interaction between the baseballs.

Yes, but baseballs are not subatomic particles. Among other things, looking at which direction they're spinning hardly changes their spin at all. The traditional line of thinking is that the laws of physics are different at the macroscopic level versus the subatomic level, but I suspect the real issue is that they *apply* differently because of the certain scale-related difference. Baseballs have a much larger mass, for instance, so gravity is a real issue for them; whereas, gravity hardly has any impact on an individual electron at all. On the other hand, a baseball has an almost exactly balanced charge, so electromagnetic force has very little impact on it; whereas, for an electron, that's a fairly big deal. These forces, though, are the two we understand best; nuclear force and weak force presumably also apply rather differently to an electron versus a baseball, but I'm not sure we understand all the details.

The whole deal with information "flowing" is anchored in the Heisenberg principle. The models I have read all suppose that if we don't know the direction of a particle's spin, it's spin direction is not merely unknown to us but actually indeterminate, i.e., could go either way. I don't fully understand all the arguments for this, but it is related in some way to the wave/particle duality of light, wherein before you measure the positions of the individual photons two beams of light interact as if they were waves, creating interference patterns, but upon being measured the photons do turn out to have very specific positions.

Re:Zonk is Jesus?!

[DavidTC]

Erm, calling those his 'religious' beliefs is a bit silly.

They were more philosophical beliefs.

Re:Zonk is Jesus?!

[geordieboy]

Experimentally, if I measure one of the photons to be "up" along direction vector N, then the other will be "down" along the same direction vector. These are just ordinary photons. There's no way that could happen without the two photons being connected in some way (unless I pre-arrange it, but this works for any direction vector N. You can't pre-arrange that, at least not via classical physics).
In quantum mechanics that happens because the two photons do not exist independently, their properties are measured by probing disturbing the entire system which is described as a superposition of photon states (some mathematics is needed to understand this properly, of course).
I recommend Feynman's Lectures Vol III for an extremely clear and logical explanation for why quantum mechanics and the "spooky action at a distance" is needed.

Re:Zonk is Jesus?!

[EntropyEngine]

He was a deeply religious man, so I'm curious as to why you think that might be silly?

Odd...

Re:Zonk is Jesus?!

[pnewhook]

I don't see how the example in the article shows any 'spooky interaction' whatsoever. There is no interaction, it's the uncertainty principle that is being circumvented by a clever experiment.

Here's my reasoning (not that anyone needs encouragement, but feel free to poke holes in this if you see something I'm missing):

The experiment is setup so that they are creating two different waves from a single one - taking a UV light wave and splitting it such that you get (for example) a red wave an a blue wave. Now it is a given that when two waves are created like this, the polarity is perfectly 90 degrees opposite, and the sum of the two distinct energies equal the energy of the original.

Now they send this through a filter. The website claims that if the filter is adjusted such that it blocks say the red wave, then the blue one goes through. Now they know the polarity of the blue wave. Then they say that obviously there must have been some kind of communication between the two for this to happen - Spooky!

What a croc. This is not spooky, the characteristics of the waves were set when they were created. Knowing one (and destroying it) means you automatically know the other because they were created simultaneously. The polarization is known and the energy is known, since the other particle is known - there is no communication going on!

Lets say we broke a pencil into two. Now we put the pieces into two bags without looking at them. It is imposssible to determine which bag has which piece or how big it is. However if we look into one bag, we now can infer everything that we want to about the second without looking specifically - there is no spooky coomunication going on between the two pencil pieces, we just knew the starting condition and what must happen when the pencil breaks.

In short, Einstein was right and nothing but a huge bottle of Tequila will convince me otherwise.

Re:Zonk is Jesus?!

[DavidTC]

Because his opposition to QM wasn't religous based. In fact, I challenge you to find a single religion that opposes QM.

He was, however, philosophically opposed to the idea that things happened 'randomly' in the universe.

Re:Zonk is Jesus?!

[Tzarius]

Indeed - that is exactly what I get from the summaries of quantum entanglement. What does it matter that until you measure the value of a property on one particle, you can't infer the value of the property on the other partice, when both had been involved at some point in the past? Unless the non-observed particle changes in behaviour before and after the measurement on the observed particle, there's nothing spooky about it.

Re:Zonk is Jesus?!

[tabrnaker]

Believing in a creator does not make one religious. Believing in a religion makes one religious.

They are two remarkably differing things.

It must be Quantum Physics Week.

Not that I'm complaining.

In what?

[Transcendent]

in scientific layman's terms

Ah, oxymoron terms... the best kind.

Re:In what?

From the article:

Electrons do not eat apples to make a quantum leap (their mouth is too small).

Nope, just moron terms.

Re:In what?

[drgonzo59]

Exactly, what's next?

Brain surgery for dummies
or
Nuclear reactor operation for idiots

Re:In what?

[LinuxGeek]

Other /. oxymorons

Slashdot stud
Girl Friend
Penetration testing

Various unrelatable quantum states.

Re:In what?

[Dogtanian]

Other /. oxymorons

Slashdot stud
Girl Friend
Penetration testing

How about....

"News for Nerds. Stuff that Matters." :)

Re:In what?

[famebait]

oxymoron terms...

Redundant pleonasms like that are really annoying, you know...

Re:In what?

Redundant pleonasms like that are really annoying, you know...

Yes, they are...

Finally!

I've been waiting for Teach Yourself Spooky Action in 24 hours.

Re:Finally!

[Tablizer]

I've been waiting for Teach Yourself Spooky Action in 24 hours.

It's right next to Brain Surgery for Dummies, Nuclear Power Plant Management for Complete Idiots, Intelligent Design for the Non-Intelligent, and War Planning for the GOP :-)

Re:Finally!

[waferhead]

Beginner's Guide to Quantum Entanglement...

I'm holding out for "Quantum Entanglement for Dummies" !

Re:Finally!

You won't have to wait long. I just saw an ad for
"NASCAR for Dummies."

Re:Finally!

[Woldry]

Cover of the newsletter of the local Mensa chapter (Cleveland) once read: "Mensa for Dummies".

Re:Finally!

[Alsee]

Bush is an expert in the last two. I just hope he doesn't try to add Nuclear Power Plant Management to the list.

-

Re:Finally!

[dangitman]

If you watch it on fast-forward, you can learn it in only 12 hours!

Re:Finally!

[cskrat]

Chapter 1: It's not just for bombs anymore.
// Describes non-military applications of atomic energy.

Chapter 2: Nuclear not Nuke-U-lar.
// What it is and how it works.

Chapter 3: The inanimate carbon rod.
// Safety systems and their use.

Chapter 4: A meltdown is not a type of open-face sandwich.
// How to know if you have a problem that needs to be fixed *NOW*

Chapter 5: Let's fire it up!
// Startup procedures

Chapter 6: Careful where you dump that.
// Waste managment procedures

Chapter 7: And then everyone turned on their blowdryers at the same time.
// Handling fluxuations in energy demand

Chapter 8: Badges? We don't need no stinking badges.
// Security measures and why they're important

Chapter 9: It glows when I pee.
// Health concerns for plant employees

Chapter 10: It only leaked a little.
// Detecting and cleaning rogue radioactive material

Chapter 11: Where do I dump the moth balls?
// extended shutdown procedures.

** sorry I don't have any of the cute little one frame comics for you. Maybe ed. 2 **

Re:Finally!

[slavemowgli]

Not to mention SAP R/3 administration for dummies (which does, in fact, exist!) and Vertex Operator Algebras for dummies (which unfortunately doesn't).

Re:Finally!

[Redwin]

Intelligent Design for the Non-Intelligent

Isn't that a best seller in Kansas, or is it just required reading?

I have to be a god damn idiot

[Wisgary]

"Normally the photons exit the crystal such that one is aligned in a horizontally (H) polarized light cone, the other aligned vertically (V). By adjusting the experiment, the horizontal and vertical light cones can be made to overlap. Even though the polarization of the individual photons is unknown, the nature of quantum mechanics demands they differ."

I just can't get Quantum Mechanics, and this is even on layman's terms!

Re:I have to be a god damn idiot

Listen, just align the damn light cones and quit asking questions.

Great Article!

[CynicalGuy]

+1 dugg

Einstein called it 'Spooky action at a distance.'

[st0rmshad0w]

I call it saturday night.....

"Quantum Entanglement"?

[artemis67]

Is that what the geek kids are calling it these days?

"Excuse me, but you stimulate the neurons in my hypothalamus. Would you like to come over to my place and study quantum entanglement?"

Re:"Quantum Entanglement"?

[Tablizer]

Is that what the geek kids are calling it these days?

Call it whatever the hell you want; geeks still won't get any.

Re:"Quantum Entanglement"?

[Robotdog]

I first read it as "Quantum Enlargement."

Re:"Quantum Entanglement"?

[Woldry]

Yes, it only gets bigger when there's an observer. ;-)

Re:"Quantum Entanglement"?

[StarkRG]

Isn't that the opposite of what usually happens?

"I swear it's usually bigger!"

Or, because I've been watching too much Lord Of The Rings: "We swears, our preacious is bigger, we swears!!"

Re:"Quantum Entanglement"?

[d99-sbr]

That would be the classical interpretation. In quantum physics the likelihood is just incredibly small.

Re:"Quantum Entanglement"?

[master_p]

That's understandable...once a particle is touched, entanglement is destroyed.

Re:"Quantum Entanglement"?

That's because you're hanging out with the wrong kind of geeks.

You have to hang out with the guys that geek out on getting laid.

sigh, digg

[alatesystems]

I saw this on Digg about 2 days ago. Even the title is a direct ripoff. I see so many ripoffs from Digg on /. every single day (except a few days later).

I read Slashdot about once every 2 days now, instead of my normal all throughout the day that I used to. My surfing time is now devoted to digg and Engadget(and other Weblogs Inc Blogs). You get better quality news with less dupes, better quality writeups, often humor, and just a better web experience in general.

But I do like the CSS on /. now. It makes it easier to do Greasemonkey scripts, and I'm running a couple of Slashdot user scripts now.

I hate to troll, but this is more of an open letter to /. editors. Just look at the Alexa numbers. There's a disturbance in the force. Here's a link to my digg news.

Re:sigh, digg

[fourtyfive]

What other title would you recommend they use? Its a... *gasp* Beginners guide... and its on... Quantum Entanglement. Shocking that the titles are so similar!

Re:sigh, digg

Since Digg doesn't have a nested comment structure it really isnt't possible to have any meaningful discussion to speak of. It's the discussion that people enjoy here, the articles are secondary (as evidenced by the lack of RTFA.) So please stay there and let us discuss the topic like adults, rather than staying here and bitching like a little crybaby. The articles are no less true because someone else posted them elsewhere a day or two ago. But then again, you're probably going to go bitch on Digg when Slashdot posts an article before them. So my message to you is this: just go away.

Re:sigh, digg

[njh]

I just had a look through digg and it lacks the one thing that makes me come back to slashdot - insightful comments. The comments were 50% juvenile drunken-louts-at-school level and the other 50% were people who didn't understand the question.

Re:sigh, digg

[MichaelSmith]

I saw this on Digg about 2 days ago

And the top article on digg links to newsforge, a stablemate of slashdot. I didn't know of any other site which puts in links to newsforge. It's a pretty obscure site outside the slashdot community.

I only had a quick look, and correct me if I am wrong, but digg seems to want people to register to view discussions. From the POV of making money from a site this is a better way to go. So would OSDN care if people moved over to digg? Dunno, have to think about this.

Re:sigh, digg

[Surt]

A lot of sites try to be slashdot and come and go. Anyone remember when kuroshin people were in here years back trying to convince everyone that kuroshin was going to be the end of slashdot? Slashdot persists for a reason.

Re:sigh, digg

You get better quality news with less dupes, better quality writeups, often humor, and just a better web experience in general.

What???

Since when has editing required no dupes, correct information, reliable and accountable sources or actual information (rather than advertising another product/site)? Keep up the effort /.!

Besides with all the weed I smoke I need to read /. to remember what I read somewhere else yesterday/last week/last month. I also need to read it at least twice so that it replaces the brain cells that I lost last night!

Since when has editing required no dupes, correct information, reliable and accountable sources or actual information (rather than advertising another product/site)? Keep up the effort /.!

Besides with all the weed I smoke I need to read /. to remember what I read somewhere else yesterday/last week/last month. I also need to read it at least twice so that it replaces the brain cells that I lost last night!

Re:sigh, digg

[Tankko]

>>The comments were 50% juvenile drunken-louts-at-school level and the other 50% were people who didn't understand the question.

Exactly!!! And what is your impression of Digg comments?

Re:sigh, digg

[Stalyn]

Dupes and the terrible editing give slashdot its charm. Come on. Also great trolling here on slashdot.... superb. Slashdot has an entire culture around it now. The crap on the front page doesn't even matter anymore. Cmdrtaco knows it. Thats why he doesn't give a shit about dupes and everything else. You could post a story that is nothing but random letters and still generate 100+ comments.

Re:sigh, digg

[mortong]

I agree. I mean remember Fark.com? That was just a fad; I don't think they even exist anymore.

I am, of course, kidding. Point is - different /. style site, different user base.

Re:sigh, digg

[Wyatt+Earp]

Yep and even now when no one is on K5, it still loads slower than here.

Re:sigh, digg

[Wyatt+Earp]

/. is it's own heat engine, it's like a big old tropical storm of dupes, bad editors, stupid people and a bunch of really smart people. But we lost the Hot Grits in 1998.

Re:sigh, digg

Nanny-nanny-poo-poo, stick your head in doo-doo.

Re:sigh, digg

[ozmanjusri]

What I'm saying is, please stay on your side.

I bet you say that to all the boys.

*Rolls over, farts, grunts, starts snoring loudly*

Re:sigh, digg

As opposed to /., where the comments are 50% were people who didn't understand the question and the other 50% juvenile drunken-louts-at-school level.

Re:sigh, digg

[thetaco82]

I'm sorry to vent like this, but we're miles off topic anyway... I love how so many people get up in arms whenever an article has been posted somewhere else first... I'm not sure if you've noticed, but the readers submit the articles. The articles link back to a source! The /. editors don't write the news, they only provide a clearinghouse for information. Get over yourself.

If you want to get bitchy over reposts, then you have slightly more ground to stand on, but it's still pretty damn petty. You should just read the articles, participate in the discussion, and stop crying.

Re:sigh, digg

[konquererz]

Why come here and blast /.? People will always read /. no matter what crap gets spunked out against it. And I havent heard anything about the 'digg effect', but I know and have experienced the /. effect first hand. Its not by accident that we keep coming back!

Re:sigh, digg

Hey you butt-ugly freak, why no anonymous comments on digg?

Re:sigh, digg

Don't let the door hit your ass on the way out.

Re:sigh, digg

[njh]

I'll pay that! :-)

Re:sigh, digg

[Tzarius]

You could post a story that is nothing but random letters and still generate 100+ comments.

Yes, definitely the first time. Especially from bored wannabe crypto-breakers. Maybe even get a few dozen +5 Insightfuls. But how many times could CmdrTaco post gibberish and still get that many comments? That's the real question.

It has some errors ...

[Y2]

Aside from the inconsistent use of plural and singular quanta/quantum, I'd be very surprised if no one was baffed by this: "In all cases, a photon's axis must be 90 degrees to its motion." Axis (of spin) and direction of polarization are linked, but not in a way simple enough to fit in this zero-math article.

"Figure 5.2 is an enhanced photograph of a photon ..." - That is more than just misleading.

Re:It has some errors ...

Perhaps the author went too far when trying to convert "orthogonal" to layman's terms?

Re:It has some errors ...

[einhverfr]

Now, the big issue that I haven't figured out is to what extent the noncommunication theorems are valid (the ones that argue that spooky action at a distance does not lead to spooky communication at a distance).

Personally I doubt the noncommunication theorems, but this may be due to my understanding. They seem entirely untestable for the reason that if you take things from a Copenhagen viewpoint, the fact is that the obvserver can't test this without breaking the experiment.

Re:It has some errors ...

[mrjb]

Got to love this one thoug: Electrons do not eat apples to make a quantum leap (their mouth is too small).

Re:It has some errors ...

[ArsenneLupin]

Got to love this one thoug: Electrons do not eat apples to make a quantum leap (their mouth is too small).

And more importantly: the article completely glossed over the fact that occasionally electrons lose energy and get dumped to a lower level, hehe.

Re:It has some errors ...

[wytcld]

Yup, confusing. Does that mean it's spinning round an axis which is aligned with its direction of motion?

Also, why is having the cones overlap effective? I suspect there's logic to that that a layman _could_ understand, but it's left unstated. Is it related to the interference patterns of ripples from two stones in water?

Re:It has some errors ...

[geordieboy]

Polarization of an electromagnetic wave is a classical concept -- individual photons have two possible polarizations, but those are NOT equivalent to the polarization of the EM wave. In an EM wave there are a HUGE number of individual photons.

Re:It has some errors ...

[geordieboy]

Incidentally, the photon spins along its axis of motion (either forward or backward). These are sometimes called helicity states. Whereas the polarization of a classical EM wave usually means the axis of motion of its electric field, which is orthogonal to the direction of motion.

Re:It has some errors ...

[mburns]

Niels Bohr actually did claim that this was untestable in his reply to Einstein. But, the standard QM theory does lead to actual tests.

Re:It has some errors ...

[einhverfr]

Niels Bohr actually did claim that this was untestable in his reply to Einstein. But, the standard QM theory does lead to actual tests.

For obvious reasons even if the noncommunication theorems are ignored, FTL communication would still be either extremely limited and/or extremely expensive due to the requirement of huge numbers of entangled electron pairs (pairs could not be reused and could only send 1 bit of info, so 1kb requires 1024 entangled pairs).

However, I am not aware of any way to test a system without a single observer so you can't test the system without such a state. Even comparing notes after would create the observation required. Indeed having two teams independantly do tests on members of entangled pairs and publish the results later would make the reader of the combination of studies the final observer by this logic. Everyone doing the experiments up until the final tally is basically in the position of Schroedinger's Cat....

Heisenberg had a somewhat different version of the Copenhagen Interpretation (as he writes it in his "Physics and Philosophy") where the Copenhagen Interp. is mostly an assumption of limitation. In other words, it is not that the the electron exists literally in an undefined state, but rather that it exists in an unknowable but probably defined state (he also claimed that measuring velocity and position infinitely accurately together would require a sort of omnicience generally thought of as impossible because it would require the simultaneous measurement of every particle in the universe).

In other words, the take one would have via this interpretation on Schrodinger's Cat is that it is not true that the cat is both alive and dead, but just that you can't know without observing which it is. This makes sense because obviously the *cat* probably knows whether he/she is alive or not but from the experiment's POV, this is unknown until observed (duh...)

Weird thought

[achurch]

In the midst of serious sleep deprivation, the following weird analogy for quantum entanglement came to mind. Maybe some of the physics folks here can tell me why it's wrong:

Suppose you take a coin and spin it on a frictionless surface in a vacuum, so that it's perfectly balanced and doesn't wobble. In theory, it will keep on spinning at the same rate forever.

Now suppose you take a second coin, identical in all respects to the first, and start both coins spinning at the same time--but with one of them 90 degrees out of phase compared to the other, so when one is "horizontal" when viewed from above, the other is "vertical".

Finally, suppose you have a way to move the coins without affecting their rotation. Move one of the coins as far away as you like from the other.

Reach out a finger and stop one of the coins. Suppose that at the instant you stopped it, the coin was horizontal. You now know that, at that particular instant, the second coin was vertical--not because the coins somehow "communicated" with each other, but simply because they both followed the same laws of physics up until you interfered.

Granted, I'm oversimplifying tremendously, but is this a semi-reasonable explanation of why quantum entanglement has nothing to do with instantaneous communication, or do I just need to get to sleep?

Re:Weird thought

[Y2]

Suppose that at the instant you stopped it, the coin was horizontal. You now know that, at that particular instant, the second coin was vertical

Sorry, no. If the coins aren't at the same place, then this term "at that particular instant" is not well defined.

The tantalizing notions of instant communication involve choosing which of two or more possible measurements to make on one of the photons (after they are separated) and the effects of that choice on the possible outcomes of a fixed or independently-chosen experiment on the other photon. Google "EPR Paradox" for a primer.

Re:Weird thought

I found myself thinking the exact same thing reading the explanation. I had always thought quantum entanglement was somehow more complex than that, perhaps the description is overly simplified?

Re:Weird thought

[achurch]

Neat, so there really is some weirdness going on. Thanks for the pointer! (I had to laugh at the Wikipedia observation that a theory that violated causality would be "deeply unsatisfactory".)

I guess I'll try and get to sleep now . . .

Re:Weird thought

[mburns]

It is just that your example is purely classical physics, it is causal, so that the QM entanglement is not shown at all, and QM entanglement for your example is not predicted by any one.

Caused states must not communicate at a distance, this is classical behavior. But, uncaused quantum transitions have the appearance of at-a-distance communication simply because quantum states do not have a classical position. Only the classical manifestations of a quantum state have their separate positions.

Quantum states themselves resemble categorical propositions in their lack of having a location. For example, where is the proposition, "Roses are red.", located? It becomes much more atractive than one first imagines to state that quantum states are actually a sort of categorical propostion.

Re:Weird thought

Suppose that at the instant you stopped it, the coin was horizontal. You now know that, at that particular instant, the second coin was vertical

The only way I can apply this analogy is that if when you stopped one coin and it was horizontal, the other coin immediately stopped spining even though no force was applied to it. How something could stop spinning w/o a force would be about as wierd as QM/QFT is.

Re:Weird thought

[evilmrhenry]

Granted, I'm oversimplifying tremendously, but is this a semi-reasonable explanation of why quantum entanglement has nothing to do with instantaneous communication, or do I just need to get to sleep?

Yes.

(ah... Nothing quite like boolean algebra.)

Re:Weird thought

The "Spooky Action" is that, at that instant, the other coin stops too.

Re:Weird thought

[mcrbids]

Let's say you "split" photon A into photons X and Y.

The, you ram photon X into something, like a brick, turning it into heat.

What happens to Y? If they're actually entangled and communicating with each other in some form, something should happen to photon Y. If not, it's just a matter of finding out Y by looking at X.

So, what happens to Y in this scenario? Anyone care to enlighten us?

Re:Weird thought

[diqrtvpe]

Unfortunately, that's not a very good analogy. What might be better is if the coins were spinning completely freely, not just along one axis, and when you stopped one the other stopped as well. But, and I may be wrong, considering that I learned this in class half a year ago, TFA struck me as significantly downplaying the communication between the atoms. From the article:

To illustrate, if an entangled photon meets a vertical polarizing filter (analagous to the fence in Figure 4.4), the photon may or may not pass through. If it does, then its entangled partner will not because the instant that the first photon's polarization is known, the second photon's polarization will be the exact opposite.

The way I learned it, it went beyond this. He may be talking about a different method of creating the entangled photons, but we were told that the photons would be like most other photons before measurement, a superposition of all possible states, rather than one in horizontal and one in vertical. Thus, the photon would pass any measurement, but it would take on the characteristics of that measurement, and its partner would become the opposite. To use the example above, the measured photon would pass through the vertical filter, becoming vertically polarized, and its partner would AT THE SAME INSTANT become horizontally polarized, and vice versa. I may have it wrong, but I'm pretty sure that's the way they teach it at my school.

Re:Weird thought

[mburns]

Yes indeed, whatever happened to X then limits the possibility of what Y is or can do. The conservation theorems of momentum, energy, and angular momentum apply in this instance, so that Y is influenced by the same sort of nonlocal entity which the conservation theorems are. Quantum states are of the same substance, it seems, as physical laws.

Do not read the article before going to bed

[Muhammar]

If you do, they will find your wave function collapsed. In seven days.

Polarization problems

[Derling+Whirvish]

Normally the photons exit the crystal such that one is aligned in a horizontally (H) polarized light cone, the other aligned vertically (V). By adjusting the experiment, the horizontal and vertical light cones can be made to overlap.

That's a too simple description of polarization. It doesn't work that way. Take a polarizing filter and shine a light through it. Add another polarizing filter but rotate it 90 degrees from the other. The light is cut off from passing all the way through both. So far, so good. Now here's the tricky part. Take a third polarizing filter and place it in between the two previous ones. Rotate it around. WOW! At some intervals you can now see through all three! With two if you rotate the second you get total blockage when the filter is at 90 and 270 degrees from the first. You get more blockage points around the 360 degrees with the in-between third one (Extra ponts: how many?)! Strange. Add another. You get even more blockage points. (How many now?) Very strange indeed. Does the experiment account for this, the real behavior of polarizing filters and not the simplistic one in the article?

Re:Polarization problems

[shawb]

The article tried to explain it without math, and IIRC that requires some basic trigonomic functions, IIRC Nsin(theta.) Ask most people about trig functions and you will just get a blank stare, or a vague memory of hearing about it in high school. Besides, the entangled photon pair in question are indeed perpendicular to each other, and so the action of polarization at other than 90degrees is a moot point.

Re:Polarization problems

[Derling+Whirvish]

Besides, the entangled photon pair in question are indeed perpendicular to each other, and so the action of polarization at other than 90degrees is a moot point.

And the polarization of the two polarizing filters that are perpendicular to each other can be defeated by adding a third in-between the others. There are circumstances (adding additional filters) where the polarization depolarizes. The model of polarized light as being filtered through a vertical gate is not wholly correct. It's much more involved. I don't understand it. But I can see how it would affect expected results of the experiment. Just as thinking of electrons as a planetary model is not correct and can lead to false assumptions.

Re:Polarization problems

Uh, you get the *exact* same effect shaking a rope throught a fence.

If you stick a third fence diagonally between the other two, it'll "move" your waves to that diagonal direction, and they'll happily make it through the third.

Re:Polarization problems

Not the same. If you're using a polarising filter it blocks the waves in other directions. It doesn't change the direction they're moving in.

Re:Polarization problems

[PhilK]

Now here's the tricky part. Take a third polarizing filter and place it in between the two previous ones. Rotate it around. WOW! At some intervals you can now see through all three! With two if you rotate the second you get total blockage when the filter is at 90 and 270 degrees from the first. You get more blockage points around the 360 degrees with the in-between third one (Extra ponts: how many?)! Strange. Add another. You get even more blockage points. (How many now?) Very strange indeed. Does the experiment account for this, the real behavior of polarizing filters and not the simplistic one in the article?


The simple NoMath(TM) answer is that passing through a polarising filter rotates the polarisation of half of the photons to match the filter.

Knowing that, it becomes trivially obvious why adding a third filter in between the first two allows light through:
(a) after the first filter all the photons are polarised the same way;
(b) when moving through the skew filter, some are blocked, but the others are now polarised in line with the skew filter;
(c) when moving through the final filter, all of the photons are no longer polarised at right angles to it (as they would have been without the skew) so some of them get through.

Re:Polarization problems

[smeek]

This bit of the article has nothing to do with polarizing filters. It's referring to BBO crystals, which are these non-linear optical components which take 2 photons and reemit them into two cones, with two different polarizations. This is useful because these two cones overlap, so that, if a photon emerges from an overlap point, it is impossible to know ahead of time what polarization it will have, but because of various conservation laws, you do know that the other photon will emerge from the other crossing point and have the opposite polarization. These two photons are entangled.

THIS EARLY POST...

...is dedicated to fighting 419 scammers, fraud lotteries et c. that use fake websites to prove their authenticity. (Inspired by the recent slashduh story.)

Everybody on broadband, load THE LAD VAMPIRE and suck the scammers' bandwidth quotas away!

Again: http://theserversdown.com/vampire/ladvampire.php

Why not open it in a separate window which you can minimise and let it run 24/7/365?

Slashdot effect at a distance?

[Tablizer]

So if that now-slashdotted server had a mirror on Jupiter, the mirror would be crawling to a hault also?

Re:Slashdot effect at a distance?

[Zaiff+Urgulbunger]

Yes.

Also, the Slashdot server can be entangled with any other server simply by linking it (no crystals required). When the /. server is entangled, we know that at any given instant, if the /. server is running, the entangled server will not and vice versa.

Tell me it ain't true - I dare ya!!

Why not 42?

[mortong]

This is like being allowed to make 20 waves in the rope each second, or 30 waves, or 40 waves, but never 25, 37, or 42. We all know that photons having a frequency of 42 is the only possible way to explain life, the universe and everything. So why won't he let us make 42 waves per second?

I want a Theory of Relativity Week

[CriminalNerd]

So I can study it.
It's the international year of physics to commemorate the 100th anniversary of Einstein's publication of his General Theory of Relativity and my Physics 11 teacher slapped the theory of relativity into my classmates' faces (and mine) right after we finished work, power, and energy unit.

I'd be grateful if somebody would declare next week as the official, "International Week of Relativity" and release lots of info on the subject because the UNIT test is next week.

On the other hand, the article is very informative and enlightening for students like me who haven't even skimmed the top of "spooky action."

(The reading speed of your eyes, relative to the typing speed of my fingers, is VEEEEERRY slow.)

P.S. Either it's just me, or you can scroll infinitely downwards at the site in the article.

How spooky action is created

Step 1) You both wear halloween costumes.

Step 2) You get drunk, then get busy. Entanglement (quantum and otherwise) ensues.

To any onlookers, this will indeed appear very spooky.

Re:How spooky action is created

[Woldry]

It's the act of observing it that makes it spooky. If there are no onlookers, then it remains in an undefined state of quantum spookiness.

Re:How spooky action is created

[whereiswaldo]

I think it's pretty comical how scientists are so serious about everything being explained with evidence, etc.. and on the other hand call matter "stuff" and certain actions "spooky". Maybe it's The Far Side scientists at work.

Re:How spooky action is created

[pdbogen]

And of course the well-known mechanics analogy of the perfectly spherical cow...

Introduction to Quantum Computer

[kahrytan]

While we are on the subject of Quantum Mechanics. Check out Caltech's website on Quantum Computers.

I would also like to put you towards HP's Research on it.

The future is quantum mechanics, no matter the subject.

Re:Introduction to Quantum Computer

[metlin]

A better source would be John Preskill's website at Caltech for his PH 219 course on QC.

Includes course material, lecture notes and problems.

Well in layman terms...

[Dark_MadMax666]

- two particles can interact with each other "magically" -that about as far as I got back in college on my physics course . I still dont get how and this article didnt make it any clearer for me.

Re:Well in layman terms...

[einhverfr]

This may be a little more complex than the article but it may be more accurate too.

Helium is the best example to use for this because it only has one suborbital for electrons and it is full. The Helium nucleus has 2 protons and 2 neutrons (yes, always there is no He-3 or He-5 isotopes that are stable). The suborbital has 2 electrons.

Electrons in a suborbital are always entangled and their spins (up or down) are fixed in opposition to the other. This means that every full suborbital contains exactly one electron spinning up and one electron spinning down. Make sense so far?

Ok, now suppose you separate these electrons by a certain distance (the amount is unimportant). These electrons will still be spinning in opposition to eachother. So the question everyone wants to ask is whether their spins are still mutually defined. So how do you test this? You flip the spin on one of them so that instead of spinning up it is spinning down or vice versa. Then you measure them both and if they are not mutually defined (as one would normally expect) you would expect them to now be the same. After all they were different and you switched one, right? Wrong. They are still mutually defined, so flipping one will flip the other.

Putting this in programmer terms.

struct electron {
spin int; // 1 is up, -1 is down
}

epair = malloc(sizeof electron);
epair->spin = 1;

printf ("Electron1's spin is %d\n", epair->spin);
printf ("Electron2's spin is %d\n", epair->spin * -1);

epair->spin *= -1;

printf ("Electron1's spin is %d\n", epair->spin);
printf ("Electron2's spin is %d\n", epair->spin * -1);

Hope this helps explain the experiments to the slashdot audience...

Re:Well in layman terms...

[at_18]

So how do you test this? You flip the spin on one of them so that instead of spinning up it is spinning down or vice versa. Then you measure them both and if they are not mutually defined (as one would normally expect) you would expect them to now be the same. After all they were different and you switched one, right? Wrong. They are still mutually defined, so flipping one will flip the other.

To elaborate on this, it's not that you can take one electron, start flipping it up and down, and communicate istantaneously with your buddy who is looking at other electron, say, 50000 miles away. Once you measure one electron, it is defined by itself andnot mutually with the other.

What you can do is making a lot of operations that will change the spin of one electron, without actually checking which is the current spin. Kinda like "reverse the current spin". All the other entangled electrons will reverse too, until you try to measure one of them.

Re:Well in layman terms...

[einhverfr]

There is a fair bit of info at http://www.aip.org/tip/INPHFA/vol-10/iss-4/p8.html that is useful here.

To elaborate on this, it's not that you can take one electron, start flipping it up and down, and communicate istantaneously with your buddy who is looking at other electron, say, 50000 miles away. Once you measure one electron, it is defined by itself andnot mutually with the other.

This is correct. The basic issue is that you have to re-entangle the electron to measure it. For FTL communication that leaves photons which creates a number of infrastructure problems. So FTL communications do not appear practical at this time.

Re:Well in layman terms...

Hope this helps explain the experiments to the slashdot audience...

I program in Visual Basic, you insensitive clod!

One major thing it's missing

[Rob+T+Firefly]

Where's the part where you travel through time and swap bodies with people in dramatic situations?

Re:One major thing it's missing

Where's the part where you travel through time and swap bodies with people in dramatic situations?

Apparently Sam came from the future and erased that part from the website. Hey wait a minute, how did I remember that?

Question...

[Wyatt+Earp]

I was reading about this one night.

What are the traps? How do they move information about the quantum state from one atom to another?

starving electrons

From the article:
Electrons do not eat apples to make a quantum leap (their mouth is too small).

How experiments say no

Brian Greene has a beautiful explanation of how your idea was proven incorrect in The Fabric of the Cosmos. Now comes my horrible attempt to further simplify it so it fits in a Slashdot post.

Your idea would be a fine alternative explanation, if there was only one property being measured. Essentially, there are an infinite number of ways to "stop the coin", different angles if you will. I.e. there are many different properties which can be measured, each of which have the same two possible values. If you measure the same property on both coins, you'll get opposite values, no matter how far apart the coins are.

But suppose you randomly choose which properties to measure on the two coins? You could randomly choose the same property to measure for both, thus guaranteeing the results will be opposite. If you measure two different properties, there's a 50% chance your results will be opposite, because there are only two possible values. Therefore, if these properties are indeed determined before you measure them, you should see opposite values more than 50% of the time.

But that doesn't happen! Experiments have confirmed that the same value is obtained exactly 50% of the time! Thus proving that the values of these properties can't have a pre-determined value.

Re:How experiments say no

[MarkRose]

If there were an infinite amount of properties though, the chances of you hitting the same property would be infinitely small, thus zero. Would it not, then, make sense that the same value is obtained exactly 50% of the time?

Re:How experiments say no

[einhverfr]

It is a little more complex than that.

As per the entangled electron and light experiments, effecting one side of it induces an effect on the other side. For example, if I take the light polarized groups and twist one half of them, say, 10 degrees, then the other side will spontaneously shift as well so as to ensure that you still have a 90% angle. Same with flipping electron spins.

The bigger issue is one of spooky communication at a distance. The noncommunication theorem states that faster-than-light communication of this sort is impossible and that spooky action at a distance doesn't translate into spooky communication at a distance, but this seems very much based on a single observer assumption (as does a lot of quantum physics: Is Shroedinger's Cat capable of observing whether he or she is alive or dead?). In this case, the problem is that from the view point of the experimentor, the entagled particle is still in an unknown state and so it is unknown whether communication occurred until experimentally verified, thus breaking the experiment.

I never understood the communication aspect...

[Vellmont]

Why does one photon have to "communicate" to the other? Take two photons, one is polarized 90 degrees from the other. You don't know anything else. At some point you observe one, and now know the polarization of the other. Why is their communication taking place?

To make an analogy,say I flip a coin and don't look at it. Then I cut the coin in half between the two sides (without looking at which side is which). I take one side across town to my friend, and keep one. I have no idea which side I have until I look at it, but once I do I also know which side my friend has across town. Where's the mystery here, because I've never been able to understand why there's any spooky action at a distance?

Re:I never understood the communication aspect...

[Woldry]

But under quantum mechanics, until you look at your half, not only don't you know which half you have, but you don't have a particular half -- instead, you have a half that has the potential to be either one.

So when you look at it, the half "decides" which half it will be, and the one your friend has across town is also "decided" somehow, if only by default. Its potential to be either half is "collapsed" into a single possibility because you looked at your half.

I don't know about you, but to a common-sense, classical understanding, that looks as though some kind of communication has taken place between the two halves. I know common sense and science are often at odds, so I have no problem with it, but the description "spooky" does seem to apply.

Re:I never understood the communication aspect...

[einhverfr]

This is an entirely broken analogy. Aside from the as yet untestible assumptions in the Copenhagen interpretation (observation creates the collapse into a definite state), quantum physics just behaves differently from the world around you.

The article isn't much better.

So you have two entangled photons at 90% polarity differences from the other. The spooky action is when you rotate the polarity of one, and the other one rotates as well because the polarity of one depends on the polarity of the other.

There is no real way of explaining this using coins.

Re:I never understood the communication aspect...

[BillyBlaze]

Even if you don't understand the necessity of the "spooky action at a distance" idea (I don't understand it either), do you really think that you, John Q. Random Slashdotter, with only a layman's knowledge of physics, have found the obvious truth that pretty much every quantum physicist has missed? Get over yourself.

Re:I never understood the communication aspect...

[Vellmont]

do you really think that you, John Q. Random Slashdotter, with only a layman's knowledge of physics, have found the obvious truth that pretty much every quantum physicist has missed? Get over yourself.

What a rude response. Did you ever think that maybe I was asking for further information on why communication was required for the explanation? Go away, troll.

Re:I never understood the communication aspect...

[Vellmont]

Thanks, you've added the key fact that always seems to be missing from every explanation of quantum entanglement that I've heard. That is, if you rotate one photon 90 degrees (without observing it) you would expect the other to photon to then have the same polarity. They don't, so obviously something strange must be going on.

Re:I never understood the communication aspect...

[Aleatoric]

Without going into a long winded explanation, we know that 'spooky action at a distance' (more technically called non-locality) is a real phenomenon based on a theorem called 'Bell's inequality'.

Here's what that theorem says, in fairly simple terms:

If the system is merely the measuring of characteristics that pre-exist, but are unknown (like your pennies), there is a certain statistical distribution that will occur over a series of measurments of those characteristics.

Quantum mechanics predicts a different distribution of the series of measurements.

A substantial number of experiments have demonstrated that the statistical results confirm the non-local explanation of events.

There's a pretty good overview (if a bit technical) of Bell's Theorem here .

Re:I never understood the communication aspect...

[BillyBlaze]

Please notice that I wasn't replying to you, Vellmont, but to Broken_Ladder, who was either trolling, or, if he believes what he said, needs to hear what I told him. I suppose it would have been more clear if I quoted him in my response, since his posts start at 0 points.

Re:I never understood the communication aspect...

[smeek]

This is incorrect. Rotating one of the photons in this pair will cause the two photons to have the same polarization afterward, even though this is undefined. If we have an entangled wave function:

|1V>|2H> - |1H>|2V>

with H and V being horizontal and vertical polarization, and 1 and 2 being the two photons. If we rotate photon one 90 degrees clockwise, V goes to H, and H goes to -V, making the new wave function

|1H>|2H> + |1V>|2V>

This says that the photons must have the same polarization when observed, though it is impossible to know what that polarization will be

Re:I never understood the communication aspect...

[Tablizer]

So you have two entangled photons at 90% polarity differences from the other. The spooky action is when you rotate the polarity of one, and the other one rotates as well because the polarity of one depends on the polarity of the other.

But I've heard that one cannot use it for distant communication. This statement implies you can. Once the first observation happens, no further "link" appears to be there.

Although I may have it all wrong, the real mystery is that each particle of the pair appears to have some kind of hidden in-synch clock or indicator (flag), yet that flag mechanism is not known.

Re:I never understood the communication aspect...

[Broken_Ladder]

Even if you don't understand the necessity of the "spooky action at a distance" idea (I don't understand it either), do you really think that you, John Q. Random Slashdotter, with only a layman's knowledge of physics, have found the obvious truth that pretty much every quantum physicist has missed? Get over yourself.

i don't know what you mean by "missed". i never suggested that scientists have missed anything. i'm just saying that a lot of ideas in QM are completely speculative, and they damned well know it.

for instance, the idea that events can be uncaused, leaving us with a non-deterministic universe. this is completely speculative, and goes completely against logic. perhaps it works well for some of their hypotheses, but it is totally untestable.

it doesn't matter how many scientists support some idea, if they have no evidence to support it. the only way you could prove this "action at a distance" idea, would be to show that a particle had no state until you observed it. but the only way to know what state it was in would be to observe it.

what's more, the concept of "observing" a particle to collapse its wave function, just means "interact with". a lot of people have this errant notion of there being a necessity for a "sentient being" to observe it. this is, of course, totally ridiculous. since every particle in the universe interacts with every other particle, through gravity and the other forces, every wave function is always collapsed, and has assumed a state.

quantum mechanics is useful at many things. but when in comes to the more obtruse, mystical aspects, it's just a bunch of fun philosphy of lattes. i don't have to be some accomplished expert in the field to say this. the evidence speaks for itself. no scientist has yet to support any of this quackery through any experimentation. the best we've got is some work to test some of belle's conjecture, and even that doesn't say very much that is concrete.

try this ad hominem stuff on somebody less accomplished, cause it won't fly with me. i'm to smart for that.

Re:I never understood the communication aspect...

i'm to smart for that.

Too smart to spell and capitalize?

Re:I never understood the communication aspect...

[michaelebrown]

I understand that we can't get instantaneous communication from measuring the state of the entangled photons/electrons, but... What precludes instantaneous communications using the timing of the measurements themselves?

Thanks

[achurch]

Okay, I've got it now. Or at least, I've got enough of it to realize that I need to go take some more physics classes to have a decent chance of getting it . . .

Baltimore spookiness

And there was a great example just today. Two entangled postings about Baltimore using cell phones to monitor traffic showed up on slashdot. Spooky!

ganja before booze

[rajafarian]

that is all

faster than light communication?

[jlowery]

Two points, A and B, are within fixed distand of pulsar P.

A and B have agreed that certain measurements of quantum entangled particles will be made a various time intervals as determined by P.

Point C lies between A and B, closer to A than B. C sends quantum entangled particles of definite polarization to A and B. At the agreed-to intervals, A does polarization measuments of particles coming from C; B measures for same polarization at the same interval (accounting for the extra time for the entangle photon to reach B).

Question: does A's collapsing of the state of the entangled photon mean that B will see less entangle photons with that polarization? In other words, will it mean that successful polarization pass-thru's at A's filter has the consequence that B will notice a distinct drop of photons with that polarization passing through its filter? If that were the case, then communication is occuring between A and B in the time it takes for light to travel the shorter distance from C to B.

Change quantum particles to entangle coin tosses. A has the head filter activated, meaning all heads that pass thru A result in no heads at B. With the filter on a A, does B see less heads than he would at other, 'normal', intervals?

Re:faster than light communication?

[einhverfr]

You have some problem called the noncommunication theorem but I suspect that this suffers from the same logical flaw as Shroedinger's cat. In essence I assume that the cat is able to observe whether he or she is alive or dead, so you have the question of what role the cat's observation has in the colapse of the quantum state.

Similarly here, you have the problem that the experiment observer has no way of knowing whether the spooky communication at a distance has occurred until the observer measures the communication via non-quantum means. This effectively means that faster than light communication is untestible in a laboratory if one subscribes to the Copenhagen interpretation.

Re:faster than light communication?

[ArsenneLupin]

Question: does A's collapsing of the state of the entangled photon mean that B will see less entangle photons with that polarization?

No. Every measure that B does along the same "axis" must correspond to what A measured. I.e. if the the entanglement is such that polarization must be opposite, B will always see the opposite of the polarization observed. by A, no matter whether B performed the measurement "before", "after" or "at the same time", (whatever that means on two spatially separed points...).

However, if A and B perform the measurement on different "axis" (i.e. in a direction offset by 45 degrees from each other), they are in effect measuring two different things, and no correlation exists. The interesting thing is that any measurement on an axis shifted by 45 degrees destroys any information that was there along the original axis, and vice-versa. I.e. if a photon passes successively through a 0 degrees instrument, then a 45 degrees, and then again a 0 degrees instrument, the two 0 degrees measurements are not necessarily the same!

The point of the "spooky action at a distance" experiment is that A and B randomly chose the direction across which they measure polarization (0 degrees or 45 degrees), and later compare notes:

• For those times where they happened to use the same axis, polarization will always be opposite.
• For those where they happend to use an incompatible axis, the observations will be uncorrelated with each other.

Because at the start of emission, it is not yet known along which axis the measurement will be performed, the measured result cannot be an intrinsic information stored in the photon at creation (the rotating coin example), so we do indeed have "action" at a distance. If the information was intrinsic, the experiment would allow us to know the polarization along two incompatible axis (0 degrees and 45 degrees) at the same time, which is not possible according to quantum mechanics.

However, because the observers have no way of influencing the outcome of their measurement, the phenomenon cannot be used for communication. However, it can be used to generate a shared one-time pad to be used along with classical communication (quantum cryptography).

The experiment would work the same way with any pair of incompatible quantum observables, for which an entangled pair of particles could be produced.

Re:faster than light communication?

[Lisper]

Here's a paper that explains why FTL communications with entangled photons is not possible:

http://www.flownet.com/ron/QM.pdf

It has some hairy-looking math in it, but the mathematical details don't really matter to the explanation.

10^33 polorization options?

[frovingslosh]

Can anyone shed any light (unpolarized) on the 10^33 states of polorization that light can have? Where did that number come from????

Not Just a Good Idea

[Doc+Ruby]

That tutorial isn't very good. The science is accurate, but it's presented in a tone that makes it seem like things "obey" physical laws, rather than physical laws accurately describing what things do. That makes it hard for a student to fill in the gaps with our imagination, because laws seem arbitrary rather than reflecting observed consistent behavior.

Over-simplifying too much

[renoX]

If your analogy worked, we could communicate 'instantaneously' using 'rotating coins': just stop it at a particular position and the other side would be able to read a message.

Whereas what's occuring in entanglement is much weirder: it is an 'instantaneous distant' action and yet it cannot be used to send data faster than light.

Quantum Physiscs demands it?

[Cabriel]

Forgive me, for I noticed something else quantum physics demands, or, rather, something quantum physics "can't" allow.

Maybe I'm just too cynical. I really can't say.

Coins are too easy

[Beryllium+Sphere(tm)]

It's weirder, more like opening a Schrodinger box at one end and taking out a live cat, thus instantly killing another cat a light-year away.

Someone link me to an explanation?

[mrjb]

I'm obviously don't have my PhD so bear with me.

The part that I *do* get is:

You cannot measure a system without altering it. That is, if you stick a multimeter in a computer you may crash it. The instrument of measurement is too course to see the state of a system without altering it. Shed light on electrons and they'll 'fly away'. In quantum physics, we're dealing with such elementary particles that absolutely every means of actually measuring the system will interfere with it.

It is statistically correct to say 'the particle is 50% here and 50% there', if chances are 50-50 for it being in one place or another.

The part that I don't get (so kindly link me to an explanation) is, just because there is no way of measuring where a given particle is, that doesn't mean it's in two places at the same time. It just means we don't know.

Two rockets fly in opposite directions at the spead of light for a year. One of them is known to carry a closed envelope saying "white", the other one carries an envelope saying "black". The envelopes are in a time-locked safe. We don't know which rocket carries which envelope. Statistically we might as well say both rockets carry an envelope saying 'grey'. After a year of travel, the captain of the first rocket opens his envelope and reads a single word. Instantly he knows what the contents of the envelope of the other rocket are. Yikes! Spooky action at a distance?

Someone hit me with a clue-bat, *please*?

Re:Someone link me to an explanation?

[novus+ordo]

*smack* : )

Re:Someone link me to an explanation?

[PaSTE]

Actually, what you've hit upon is something called the "hidden variables" theory of quantum mechanics. For a while after the spookiness of entanglement was figured out, vis. the Einstein-Podolsky-Rosen paradox, many physicists thought just like you do--that there was some hidden variable within the system that we could not measure, but which determined the state of the system exactly. They figured for instance that, if a certain decay process produced two photons, one left-polarized and one right-polarized, then there was some feature of the decay which determined which othe the photons is left-polarized and which right-polarized, so that our measurement of one did not "change the state" of the other photon, if merely revealed its pre-determined polarization.

The hidden variables theory of quantum mechanics was disproven by a physicists named John Bell. In his method, he began by assuming that these "hidden variables" existed, then, using geometric arguments and the postulates of quantum mechanics, derived a set of inequalities which showed no physical theory of local hidden variables can ever reproduce all of the predictions of quantum mechanics.

It's not intuitive at all, but Bell's argument is sound. Entanglement and action-at-a-distance is real, and not due to the system's state being pre-determined by hidden variables.

Re:Someone link me to an explanation?

[stevelinton]

The part that I don't get (so kindly link me to an explanation) is, just because there is no way of measuring where a given particle is, that doesn't mean it's in two places at the same time. It just means we don't know.

What you're hankering after is a "hidden variable model". There is a variable that we can't observe, but it has a definite value. Unfortunately, no simple hidden variable model can explain observations. There are lots of ways of demonstrating this, but all have some complexity.

One of my favourties is due to John Conway and some other people, and it goes like this.

Physics tells us that if we pick any set of three directions at right anfles (eg up, backwards and left) and measure the squared spin of a simple particle (like an electron) in each of them, we get two 0s and a 1 in suitable units. The order of the three measurements doesn't matter.

Now, Conway et al found a set of points on a sphere (ie a set of directions) out of which you can choose lots of triples that are all at right angles. What you can't do is label these points 0 and 1 in such a way that every such triple has two 0s and a 1. So there can't be a hidden variable for the squared spin in each direction, because which one you get depends on which other ones you measure, even though these measurements don't interfere with each other. Using entangled particles and a bit of jiggery pokery you could even do the three measurements at the same time and far apart so there would be no time for information interchange.

A similar, although more subtle effect occurs in EPR. You give each "rocket captain" a choice of directions to measure the polarisation in, and you find a degree of correlation that you could not expect purely from a hidden variable model.

Re:Someone link me to an explanation?

[Some+Bitch]

Forgive me if this is wrong, my physics ended at A level. As I understand it (continuing your analogy) if you rub out black on your card and write white instead, the other card will now read black. With photons if you rotate the polarity of one the other also rotates, that's the spooky bit.

Re:Someone link me to an explanation?

[waxigloo]

Re: Your 2 rocket example:

Classical correlations are not suprising, and your 2 rocket experiment is the perfect example of a classical correlation.

The thing you can do with quantum variables (like spin, polarisation, whatever you are using) that you can't do with classical quantities is measure in a different 'basis'. (It is essentially the same as doing a basis change in linear algebra: if you write down a vector in different bases, the projecting the vector onto the basis vectors will give you different probablilities.)

Now in the quantum experiment the weird thing you can do is wait until the last possible moment to choose which basis you are going to use (i.e. wait until the photons have been created and are in some definite state) -- then you can try to 'trick' the photons. But, if you DO this experiment, the correlations always exist, no matter what basis you choose.

This experiment is the basis for Bell's inequalities, which prove that a 'local hidden variable' theory can NOT explain these correlations.

Re: 'there is no way of measuring where a given particle is'

That is not true: There is a way to measure...but when you do measure where the particle is you 'collapse the wavefunction' and you localise the particle to a particular location. But if you DON'T measure the location of the particle, the interference pattern that arises can only be explained if SOMETHING was at two places at once (this something is the probability amplitude for that particle).

Re:Someone link me to an explanation?

[Twinbee]

Thanks for asking this - so concise too. I've wondered about the same question for years, without any newspaper, pop science magazine, TV programme, website or ANYTHING actually asking or providing info to that 'super obvious' question. Like you, I've always thought (or used to think) that just because we don't know, it doesn't mean that there's not a definite reality behind it all. Contact me for $5 if you have a paypal account (through my website).

Thanks also to the responders mentioning the hidden variables theory, and how it doesn't quite account for the data.

ach, no

[Quadraginta]

Goodness, no, this is not an accurate analogy. Here's a formally equivalent analogy that should raise your suspicions:

Take two bullets and fire them in opposite directions from identical guns. If you measure the distance of bullet #1 at time t, you will find, amazingly, that bullet #2 has traveled exactly the same distance, but in the opposite direction. Hopefully that doesn't strike you as an amazing result.

What both of our thought experiments say is that if you establish a correlation in a composite system (the two bullets, or your two coins), and you expand the system without doing anything to mess the correlation up, then, amazingly (not!) the correlation will be preserved no matter how large the system gets.

What QE involves is something different: it says you can create a correlation after you have expanded the system, and in less time than it would take any kind of signal or force to cross the distance involved (in fact, instantaneously as far as anyone knows). The correlation can't be used for communication because you can only verify the results of the correlation by communicating the results of measurements on the two parts of the system, which, of course, you can only do at the speed of light.

The whole business arises from the fact that we don't yet understand what happens when the "wavefunction collapses." We know that measuring a quantum system instantly transfers it from the quantum state it was in into a new one (the one consistent with our measurement). So far as we know, this happens instantly over the entire volume that the wavefunction occupies. The problem with this is that it seems dangerously close to violating relativity, because it seems something is being transmitted instantaneously over finite, possibly large, distances.

Relativity is not yet in trouble because we have no good theory of quantum measurement, no knowledge of how a wavefunction collapses, so we can't apply the restrictions of relativity to the internal workings of the collapse. Relativity may never be in trouble, because the collapse may be an epiphenomenon, an event that seems to involve transmission of information but which really doesn't.

Here's an example of an epiphenomenon: point the world's biggest laser at the Moon and look through a telescope at the dot. Aim the laser at one side of the Moon, and then swing it over to the other side quickly. If it takes you 0.25 seconds to move the laser's aim, how long will it take the dot to "travel" across the face of the Moon? 0.25 seconds, clearly, for a "speed" of 22,000 km/s. If you can change the aim of the laser in less than about 0.15 seconds your dot will "travel" across the surface of the Moon faster than the speed of light.

But that's because nothing is really moving. The "motion" of the dot is just a fiction in your mind you create to help describe what you're seeing, because what you are seeing looks superficially similar to what you see when a real object moves. But there's no more real motion here than there is horizontal motion when a group in a stadium does "the wave". In the same way, the "transmission" of information in a QE experiment may turn out to be an epiphenomenon of a higher order, something that "looks" like transmission but really isn't.

Proof

[marx]

It's hard to accept a proof of quantum mechanics which itself uses the postulates of quantum mechanics to carry out the proof. It would be much more convincing with an experiment which disproves the "hidden variables" theory. Has such an experiment been carried out?

For example, if it is indeed possible to alter the state of photon B by altering the state of photon A, then it should be possible to send messages by altering the states, via Morse code for example. Has anyone been able to do that? If not, why not?

Re:Proof

[smeek]

Check Wikipedia for "Bell Test Experiments".

The short answer is yes, of course it has been tested. No one would accept such a theory, or quantum mechanics in general for that matter, without experimental results that agree with its findings.

Re:Proof

[marx]

Well, this is what Wikipedia says on Quantum Entanglement:

However, at this time classical information cannot be transmitted through entanglement faster than the speed of light.

So what I asked for, i.e. sending Morse code through the states of entangled particles is not possible. This means that the term "action at a distance" is misleading, you cannot actually instantaneously change the state of entangled particle B by changing the state of entangled particle A. I'm sure Bell's Test demonstrates something, but it doesn't demonstrate "action at a distance".

Isn't it supposed to be instantaneous?

[Livius]

I find this explanation even more watered down than most. I have yet to see a quantum entanglement scenario that distinguishes quantum mechanics and special relativity. Photons travel at the speed of light; therefore - from the photon's perspective - the distance travelled is zero. Of course they're entangled - there's a frame of reference where they are in the same place!

I know quantum entanglement is supposed to say more than that, but the layman's explanations always seem to be missing the part that isn't explained by special relativity alone.

Because neither has a specific polarity...

[wurp]

until you measure one. Firstly, for quantum entanglement to be there, both photons must have come from a single event, like an electron-positron collision. They come out of that event with no particular polarization, but rather a quantum superposition of polarizations. This is evidenced by the fact that they have a 50-50 chance of passing through any polarization filter, regardless of its orientation.

However, once one of them *has* passed through a polarization filter, the other one must have a polarization of 90 degrees of from the other. So if two people distant from one another have two filters set 90 degrees from each other, and if one photon of an entangled pair passes through one filter, the other must pass through the other filter.

Heisenberg, DeBroglie, Orbitals

[sanman2]

I too am not a physicist, but still enjoy reading about topics like this. I want to make a comment however, by way of analogy, on the nature of Heisenberg Uncertainty and DeBroglie Wavelength.

When I was in highschool, our biology teacher asked us to look throgh a microscope at a drop of water under a slide. In the view I could see a fuzzy/blurry-looking speck of dust, which was apparently jiggling. The teacher explained that the jiggling of the speck was due to it being battered by water molecules in a phenomenon known as "Brownian Motion".

I've never heard Heisenberg Uncertainty or DeBroglie Wavelength described in that manner before, but I want to ask if these phenomena could likewise be considered a form of Brownian Motion.
Ie. the intrinsic DeBroglie wavelength of a small particle could be due to it being buffeted by some minute forces occurring in the space surrounding it (aka. the Quantum Vacuum), and likewise the associated Heisenberg uncertainty would be the fuzziness/blurriness from that jiggling.

In school, I never understood why an electron's orbital was called a probability cloud, because it was just so counterintuitive. But if you use that jiggling analogy, one could visualize a tetherball attached to a post, where the ball is the electron, the post is the nucleus, and the tether is the charge attraction between them. Once again, the buffeting from the surrounding Quantum Vacuum would cause the tetherball to bop around under the constraints of the tether. If you used time-lapse photography, that tetherball might show up as a Probability Cloud, rather than in a single position.

I think good science should always strive to make the explanations as intuitive as possible, rather than hiding behind cryptic phrases such as "spooky action" and "counter-intuitive quantum behavior". When science can't explain things intuitively, then in my opinion science is failing to do its job, and more efforts need to be made to come up with better analogies. Good analogies make the difference between enlightenment and ignorance.

Comments, anyone?

Re:Heisenberg, DeBroglie, Orbitals

Maybe the "electron-is-actually-a-cloud" model seems counter-intuitive because it is wrong. Accomplished people like Carver Mead (just Google him) offer alternative models that give the same answers. Its almost herasy to question quantum physics, but so was saying the Earth is round.

But how does the link between two particles work?

[master_p]

The article was good for me which I do not have a formal education in physics. One thing the article says it will explain, but it does not, is how does the link between two particles work. The theory says that if one of the particle's spin changes, the other's spin will change accordingly, no matter what the distance. But how does that work? what is the link between the two particles?

how to communicate through time with entanglement

[Brendonian]

For a few years I've wondered if you could use entanglement to communicate back in time.

Anyone familiar with "realistic" time travel predictions knows if you have a worm hole and spin move one end around really fast then each end will be in a different 'time frame'. Entering one end will bring you out in a different time.

By the same thinking I wonder could you take a pair of entangled particles and move one around really fast......then spinning one should cause the other to respond, but in a different time.

Anyone know why this wouldn't work?

Entangled Particle Encrypted Communication

[fedrive]

This website has been illustrating a concept for Quantum Entanglement for many years with text and gif files.

http://colossalstorage.net/home_entangled.htm

GYEEEAAAARGH

[Tzarius]

Take two bullets and fire them in opposite directions from identical guns. If you measure the distance of bullet #1 at time t, you will find, amazingly, that bullet #2 has traveled exactly the same distance, but in the opposite direction. Hopefully that doesn't strike you as an amazing result.

What both of our thought experiments say is that if you establish a correlation in a composite system (the two bullets, or your two coins), and you expand the system without doing anything to mess the correlation up, then, amazingly (not!) the correlation will be preserved no matter how large the system gets.

What QE involves is something different: it says you can create a correlation after you have expanded the system, and in less time than it would take any kind of signal or force to cross the distance involved (in fact, instantaneously as far as anyone knows). The correlation can't be used for communication because you can only verify the results of the correlation by communicating the results of measurements on the two parts of the system, which, of course, you can only do at the speed of light.

You didn't finish your analogy! Please tell us the analogy between the bullets and "creating a correlation after expanding the system". I want to understand this, I really do.

Instantaneous communications - timing, not measure

[michaelebrown]

I understand that we can't get instaneous communication from measuring the state of the entangled photons/electrons, but... What precludes communications using the timing of the measurements themselves?

Re:But how does the link between two particles wor

[SlippyToad]

The person who answers your question will be up for a Nobel in Physics.

Re:how to communicate through time with entangleme

[Eli+Gottlieb]

Because "moving one around really fast" relies on some of the time effects of General Relativity (as superceding Special Relativity), which we don't really know how to combine with anything at the level affected by Quantum Mechanics and entanglement.

The math just isn't there.