Open-Destination Quantum Teleportation 487
Roland Piquepaille writes "An international team of physicists has entangled five photons for the first time in the world, reports Technology Research News in "Five photons linked." Why is this important? Because it's the minimum number of qubits needed for universal error correction in quantum computing. In other words, they found a way to check computational errors in future quantum computers. The physicists also demonstrated what they call 'open-destination teleportation,' a way to teleport quantum information within and between computers." "They teleported the unknown quantum state of a single photon onto a superposition of three photons. They were then able to read out this teleported state at any one of the three photons by performing a measurement on the other two photons," adds PhysicsWeb in "Entanglement breaks new record
". This will be used in about ten to twenty years to move information among quantum networks. You'll find more details and references in this overview."
This is what a normal person just read above. (Score:4, Funny)
Or perhaps... (Score:2, Funny)
Re:This is what a normal person just read above. (Score:5, Informative)
This was predicted a while ago by Alexei Kitaev [caltech.edu], and Anton Zeilinger [univie.ac.at] had a preliminary demonstration of a basic q.t. system a while ago. I would imagine that this is just an extension of their works.
Re:This is what a normal person just read above. (Score:4, Funny)
Re:This is what a normal person just read above. (Score:5, Funny)
Ah, much better. Thank you for putting it in layman's terms.
Now, if you'll excuse me I think I feel my head exploding
Re:This is what a normal person just read above. (Score:5, Informative)
But they are entangled! (Score:3, Insightful)
If the particles are entangled, and it observe one of the observer ones, isn't that going to change all of them because they are still entangled?
or do you unentangle them before you observe them? Can you unentangle particles without changing their state?
Re:But they are entangled! (Score:4, Informative)
yes, any observation on a set of entangled particles changes the state of the whole set.
or do you unentangle them before you observe them?However, if you do it appropriately it does change it in such a way, that (a) your measurement tells you nothing about the unknown state and (b) the unknown state is still encoded in the state of the unmeasured particles.
not before - but the act of measurement disentangles the measured particle from the rest. It may lead to *all* particle being disentangled (e.g., if they were in a state |00000>+|11111> and you measure in the basis {|0>,|1>}) or it may leave the unmeasured particles entangled (e.g., if you measure in the basis {|+>=|0>+|1>, |->=|0>-|1>}).
Can you unentangle particles without changing their state?no, since the state they are in is either entangled or not, disentangling them implies changing their state.
However, the 5-qubit state may be a *redundant* encoding of another state Psi (of fewer qubits). Then it is possible to change the overall state (either by measurements or normal time-evolution) such that one ends up with a single qubit in the state Psi.
This can be useful, since it may allow to if something has happened to the state encoded *without* learning anything about the state. This is the essential idea of quantum error correction: encode in a big (say 2^5-dimensional) space the state of a two-dimensional system. Detect, whether the state has moved out of this subspace (i.e. an error has occurred) but do it such that you do nott distinguish the two states in the subspace (thus leaving it untouched).
Re: (Score:3, Informative)
Quantum Humor (Score:5, Funny)
Werner Heisenberg [aip.org] was pulled over...
Re:This is what a normal person just read above. (Score:5, Informative)
It can have any state, in between 0 & 1 -- just that you are not permitted to know what state it is in.
Re:This is what a normal person just read above. (Score:4, Funny)
It can have any state, in between 0 & 1 -- just that you are not permitted to know what state it is in.
Kinda like a women then?
RegardselFarto
Re:This is what a normal person just read above. (Score:5, Informative)
For the parent: the state of all bits become fixed when observation of any member is read; this is simply a noise correction for what is read, a sort of redundance.
For this: this effect does not supply long distance communication. All it does is supply uncrackable encryption. A signal (probably radio) still needs to be sent in order for information to actually be communicated.
Re:This is what a normal person just read above. (Score:3, Informative)
Re:This is what a normal person just read above. (Score:5, Funny)
you forgot that it is one step closer to being able to run Longhorn!
Re:This is what a normal person just read above. (Score:5, Funny)
The day some idiot turns decision making over to computers is the day I start the Butlerian Jihad.
Re:This is what a normal person just read above. (Score:3, Informative)
No, you don't. This is a common misconception about quantum teleportation. You still need a second, non-instantaneous communication channel to complete the information transaction.
Re:This is what a normal person just read above. (Score:3, Interesting)
Re:This is what a normal person just read above. (Score:5, Informative)
The problem is this: you cannot actually transfer information using this scheme, only randomness. This is because when you're making the change in the original particle, you cannot control HOW the change is made.
Let's use pennies as an example, pretending that we can "entangle" them like we can subatomic particles so that if two spinning pennies are entangled, if one stops on heads, the other stops on tails, and vice versa. If you take two spinning entangled pennies, then send one of them a few light seconds away, you have a situtation similar to the way these experiments are set up.
So we have these two spinning pennies... Now let's just stop the one still in front of us. Ok, it landed on heads. Now we know the other has just landed on tails. Yet we have not transmitted useful information because we didn't FORCE the penny to land on heads, we just STOPPED the penny. There is no way of controlling how it was going to end up, so all we have transmitted is randomness. This is great for generating randomness for encryption, but you can't communicate with it.
Also, let's set up a different scenario. We'll say that instead of using the states of the tangled pennies to try to transfer information, we'll just use the fact that we stopped them. Now if we have, say, 1000 total entangled pennies (each side having 500), we can agree on a "pennies stoppped per second" rate that is used to transmit information. If we stop 1 penny per second, it's a ZERO bit, and if we stop 2 pennies per second, it's a ONE bit. This means we can transmit a series of 250 ones, or 500 zeroes. But this is instantaneous, so it violates the idea of faster-than-light communication, right?
Actually, it doesn't. However far apart those pennies are when you set up the communications, the "remote half" had to travel at most the speed of light to get there. So, you do not get any increase in the total communication speed.
(You can read more details about quantum entanglement [wikipedia.org] on Wikipedia.)
oh please (Score:4, Insightful)
Re:oh please (Score:3, Informative)
http://science.nasa.gov/headlines/y2002/27mar_sto
Re:oh please (Score:4, Insightful)
Re:oh please (Score:5, Funny)
Re:oh please (Score:4, Funny)
I'm going to download mp3s of all of next year's songs, copyright them myself, and release them into the public domain! Bwahaha! Take that, RIAA!
Re:oh please (Score:3, Informative)
Re:oh please (Score:5, Interesting)
Lets say we have a train driving past the earth at half the speed of light, from left to right. We have You standing still on earth with your Magic Instant Communication Device. At the (f)ront of the train we have Fred. At the (b)ack of the train we have Bob. In the exact (m)iddle of the train we have Milly. To make it easy lets assume the train is two light years long.
Now, as the train passes the earth, when it is exactly half way and you and Milly are at the same spot, you signal both Fred and Bob to turn on signalling lights "simultaneously". You will first see both of those signal lights simultaneously one year later, meaning Fred and Bob simultaneously turned them on 1 year ago. From YOUR point of view all is well and good, but that's only because we STARTED from your point of view in the first place.
Now lets look at YOUR view of what happens to MILLY, and then lets look at it from MILLY's point of view.
Milly has moved off to the right at half the speed of light. Fred's light has to pass Milly first, before it reaches you. In particular you'd say it would reach her 8 months after you hit your magic button. Also, by the time you see Bob's light from the back of the train Milly will he a half-light year off to the right. It will take a total of two years for Bob's light to catch up to Milly.
So according to you, Milly sees Fred's signal 16 months before Bob's signal.
Now lets go to Milly's point of view. As far as she is concerned her train isn't moving at all, it's YOU that is flying past at half the speed of light. Fred is motionless relative to her, one light year* in front of her. Bob is motionless relative to her, and one light year behind her. For her the speed of light is still one light year per year and it takes one year for a light to cross either half of the train to reach her. When she sees Fred's signal 8 months after you hit your button she knows Fred had to signal a year before that, or 4 months BEFORE you pressed your button. When she see's Bob's signal two years after you hit your button she knows Bob signaled a year AFTER you pressed your button. Milly can walk up and down the train and measure speeds and distances and all of the laws of physics, and the fact is that for her Fred signaled 16 months before Bob did, not simultaneuosly.
Now lets let Milly reach out and tap your Magic Instant Communication Device while you go zipping past them. She "simultaneously" tells Fred and Bob to turn on their signal lights. Fred's and Bob's signals zip down the train towards her at the speed of light, each singal covers the one-light year length in one year. Milly sees both signals simultaneously. Whoops! Your Magic Instant Communication Device is broken, it does something different depending on who presses the Magic Button.
If we add in a second train travelling in the opposite direction then no matter how you attempt to "fix" your Magic Instant Communication Device there will always be someone somewhere who can send a signal into the past and violate causality. Explaining how and proving it under General Relativity is the stuff of physics papers, not slashdot posts.
Nobody however says that wormholes would violate the laws of temporal causuality.
Flat-out false. Try Google, in particular search on Wormholes and Closed Time-like Loops. A "closed time-like loop" is a path you can fly along to get back to where you strated at the same time (or before) you left. You will find tons of refferen
In other news.. (Score:3, Informative)
Re:In other news.. (Score:4, Insightful)
and "adds PhysicsWeb in 'Entanglement breaks new record '."
How much credit do you want them to give?
Teleportation? (Score:4, Funny)
Re:Teleportation? (Score:4, Funny)
Re:Teleportation? (Score:3, Funny)
They got it working already (Score:4, Funny)
Very obligatory Futurama (Score:4, Funny)
Professor: No fair! You changed the outcome by measuring it!
Re:Very obligatory Futurama (Score:3, Funny)
Actually both
Re:Very obligatory Futurama (Score:3, Funny)
Re:Very obligatory Futurama (Score:3, Informative)
Another gem from the horse race is the "Horse D'ouevres" stand, which claims "All our horses are horse-fed, for that double horsed-in goodness."
Make it so! (Score:2, Funny)
Enterprise, one to beam up.
Misunderstanding... (Score:3, Insightful)
Re:Misunderstanding... (Score:2)
Re:Misunderstanding... (Score:5, Informative)
Ofcourse, if you are talking about the inherent parallelism in q.c., you are right.
Re:Misunderstanding... (Score:5, Informative)
Yes. They can transmit the data, but they cannot preserve the data without losing information. This is one of the primary ideas behind Quantum Cryptography, which forbids eavesdroppers from creating copies of the transmitted data.
I'm not talking about approximation -- I'm talking of copying the basic qubit as a function of quantum states -- no two quantum states can be copied, and if this were possible it would result in some funny stuff like causality.
You don't have to believe me, see for yourself - No Cloning Theorem [wikipedia.org].
Re:Misunderstanding... (Score:3, Interesting)
Re:Misunderstanding... (Score:3, Informative)
Actually, it's much more complicated than that. What I described above is basic quantum teleportation, which has bee
Faster than Light (Score:2, Interesting)
Re:Faster than Light (Score:5, Informative)
Teleportation was achieved a long time ago by a bunch of folks at Innsbruck [univie.ac.at], led by Prof Anton Zeilinger [univie.ac.at].
Re:Faster than Light (Score:3, Interesting)
With error correction you should now be able to do this. So, my question is, if you can send a message between two points instantaniously, why could you not do this between say, A spaceship heading to Alpha Centauri and Earth?
Re:Faster than Light (Score:5, Informative)
But - no useful information can be transmitted between the two systems. This is because the information in itself is given by probabilistic superposition of the states. For instance, you have a Qubit defined as the superposition of states, given by |psi> = a|0> + b|1> - so you can only find out when they are absolute states (0) or (1), and not in between -- and that will not happen at speeds less than the speed of light. In order to find out what state the system is in (in between 0&1), you will need to be able to copy the state, which is prohibited by the No Cloning Theorem [wikipedia.org].
So, to answer your question - you *may* be able to achieve instantaneous transmission of information, but you can never observe that information in a causal fashion less than the speed of light. Did that make sense?
Re:Faster than Light (Score:3, Interesting)
What if that information is a person? What happens then? Does the person get instantaneously transmitted to the other side or not? e.g. you transport the blackbox, even though you never look inside, the blackbox still gets to the other side.
Or is it impossible to set the state of the origi
Re: (Score:3, Interesting)
What this means (Score:3, Funny)
Of course, during upload their body would have been destroyed. Anyhoo, it sure will suck to have been the last person to think they had to die.
And that, is the point of this article. Fodder for postings such as this. Etc.
[And yes, I did have to use a spell-checker to get "consciousness" right, what are else computers for, if not for spelling?]
Re:What this means (Score:3, Insightful)
You guessed wrong.
Already done? (Score:4, Funny)
Re:Already done? (Score:4, Funny)
Finally... (Score:4, Funny)
Marilyn Chambers to the transporter room! (Score:4, Funny)
See honey, I wasn't lying when I told you I knew nothing about it!
One of those physicists must have teleported that donkey porn onto my computer!
The Wiki-Tome (Score:4, Informative)
To be perfectly honest, quantum computing scares me to some extent. Things like PGP encryption and other very sensitive operations could, quite literally overnight, be blown away and dangerously shift power quickly. Then again we will also usher in a new age of unlimited (well, from a 2004 perspective, matter itself ultimately has a limit for storage and processing) computing that can make engineering in all fields like nothing we have seen before. And, the best part, we will see it in our lifetimes.
Re:The Wiki-Tome (Score:4, Interesting)
Maybe. This is the wrong time and political environment for these types of advances to be occuring, IMO. I could be wrong, but I see governmental control on this technology for the foreseeable future. There isn't more now because they really don't have anything that could be mass produced, but when we reach that point, get ready for the "terrorists could do xyz with this!" hyperbole and heavy legislation to control it.
I guess if they just limit it to universities and favored businesses we might still get to see some of the fruits of it. Let's hope I'm wrong. The faster we get quantum computing into the hands of as many people as possible, the faster our technology will advance.
Re:The Wiki-Tome (Score:3, Interesting)
During World War II, many mathemeticians worked for the governments of the UK and USA to break and design cryptographic tools and methods.
It's only recently that some of them are being allowed to tell of what they have done.
One can only imagine what is being developed these days that we won't know about until many years later.
Re:The Wiki-Tome (Score:3, Insightful)
Re:The Wiki-Tome (Score:5, Informative)
While I appreciate your optimism, I must tell you that the chances of QC taking a giant leap within the next 25 years is quite low.
Sure, people will build preliminary quantum computation elements, and will perform simple operations. But to have a system comparable to existing computers will take a really, really long time.
For one, the resources needed to perform and control such operations is really expensive, and occupy enormous amounts of space. Even technologies used today to achieve the quantum hall effect (one of the primary requirements if you are building a q.c.) is really primitive. For instance, consider MIT's carbon-nanotube technology -- the problem is that while you can achieve q.h.e., not two systems can be duplicated perfectly. Other methods such as building solid state elements to do this (which is what I work on) have been quite unsuccessful.
That, and the fact that we are yet to develop a good enough quantum error correction system. The thing is that in order for QC to take off big time, other areas (material science, nanotech, theoretical CS and information theory, etc) need to progress significantly.
Sure, you may see some primitive QC within the next 40 years or so. But the probability of you seeing a QC capable of, say, solving Primes in P or one that can play you a DVD is quite low. Just my two cents. And yes, IAAQP (I'm a quantum physicist).
Re:The Wiki-Tome (Score:5, Interesting)
And today, we have half-decent computers - a good 182 years later. Even assuming that the technology is exponential, and the necessary developments in the other areas are made in the next 25 years -- it would atleast be another 34 years after that for QC to take off bigtime and for us to have the equivalet of today's computers (or better) in QC.
I'm not being pessimistic, just being honest about how I feel, as someone who works in this area.
Re:The Wiki-Tome (Score:4, Informative)
http://qubit.nist.gov/FoQuS/foqus.html [nist.gov]
Quantum computers don't require any fundamental new breakthroughs, they are now almost an engineering problem. There is a real chance that the manhattan-style approach being taken by NIST will succeed in the next 20 years.
They're not equivalent. And they don't need to be.
Limited use? (Score:5, Funny)
In quantum teleportation, complete information about the quantum state of a particle is instantaneously transferred by the sender, who is usually called Alice, to a receiver called Bob.
So, this would only be useful for sending information about a quantum state to guys named Bob? The quantum state thing is limiting enough, but c'mon ... Bob?
Well, tell you what. I'm changing my name to Bob. If you can't beat them, join them. I mean, these guys will be the information uberlords of the future. People will queue up to them, asking 'Did anything come for me yet?' And they will go, like, 'Show me the money!'
The Bobs of the future will be ultra-popular and rich.
...
Yes, I haven't taken my medication today? Why do you ask? :P
Re:Limited use? (Score:5, Informative)
Re:Limited use? (Score:5, Funny)
Re:Limited use? (Score:3, Funny)
So that's why TPTB named the main character of Sliders [imdb.com] was named Quinn Mallory?
(Offtopic.) That show is frustrating! So many cool nuancies.... so many bad plots....
Re:Limited use? (Score:3, Informative)
Re:Limited use? (Score:2)
Future or syntax? (Score:5, Funny)
Just how far in the future will we be able to check? Should be a great aid to debugging! But what happens if I fix a problem that causes my great grandson to come back in time to help me to meet my wife? Oh, wait.
Lets clear some things up... (Score:2, Interesting)
Transportation like on star trek is a long ways off... however we are on trak for the star trek universe... transparent aluminum in 20 years according to scotti when they went to 1985 earth... we've discovered it now...
I'm still waiting for my sub
Re:Lets clear some things up... (Score:3, Informative)
and it wasnt that new, either. sapphires are natural examples of translucent alumina.
Great to see (Score:2)
As I understand it, what this is saying is that they have not discovered a way to have error correction in a quantom network. AFAIK this quantom network is not referring to a network of computers as we would think of it today, but is basically saying that in a network of entangled particles, or a network of qbi
i'll believe in it when i see it (Score:2, Insightful)
Buzzwords (Score:2, Interesting)
What we don't know (Score:4, Interesting)
What we may be seeing is the physical evidence that space and time are not much at all like we think they are.
Entanglement seems to allow things far away from each other, that used to be close to each other, to react to each other like they are still close to each other.
Science fiction fans will understand that the most likely explanations for that kind of thing are also likely to be wrong.
I look forward to a better understanding of this kind of behavior because it will allow us to better manipulate and control the way our area of the universe works.
For those who think of this as star trek blek, try putting yourself in the place of someone 200 years ago who was told that someone who lives in England would be able to visit someone in the colonies by a trip of only 3 hours.
dzimmerm (who is at work and whose account does not seem to recognize his password and who does not have any way to pop his home email from work due to SPIT, filtering, and SPIT lotus notes)
Re:What we don't know (Score:5, Informative)
Actually, this is physical realization of quantum principles that have been known for about 70-80 years. And all of those quantum theories were already verified at the fundamental level. There's no new fundamental physics theory being discovered here, the strangeness of relativistic time/space at the quantum limit (ie, Quantum Field Theory) has been quite well developed and understood for a long time now.
This is more like an applied physics or engineering verification of a quantum applied physicists sketch for quantum error correction of quantum teleportation.
Now if physicsists were able to finally merge gravitation with quantum mechanics, that would be huge and just might float your battleships. But this quantum teleportation is certainly not that at all.
I do not pretend to understand. (Score:2, Funny)
Quantum Teleportation explained. (Score:5, Interesting)
In 1993 an international group of six scientists, including IBM Fellow Charles H. Bennett, confirmed the intuitions of the majority of science fiction writers by showing that perfect teleportation is indeed possible in principle, but only if the original is destroyed. In subsequent years, other scientists have demonstrated teleportation experimentally in a variety of systems, including single photons, coherent light fields, nuclear spins, and trapped ions. Teleportation promises to be quite useful as an information processing primitive, facilitating long range quantum communication (perhaps unltimately leading to a "quantum internet"), and making it much easier to build a working quantum computer. But science fiction fans will be disappointed to learn that no one expects to be able to teleport people or other macroscopic objects in the foreseeable future, for a variety of engineering reasons, even though it would not violate any fundamental law to do so.
In the past, the idea of teleportation was not taken very seriously by scientists, because it was thought to violate the uncertainty principle of quantum mechanics, which forbids any measuring or scanning process from extracting all the information in an atom or other object. According to the uncertainty principle, the more accurately an object is scanned, the more it is disturbed by the scanning process, until one reaches a point where the object's original state has been completely disrupted, still without having extracted enough information to make a perfect replica. This sounds like a solid argument against teleportation: if one cannot extract enough information from an object to make a perfect copy, it would seem that a perfect copy cannot be made. But the six scientists found a way to make an end run around this logic, using a celebrated and paradoxical feature of quantum mechanics known as the Einstein-Podolsky-Rosen effect.
Read just how this effect works, here. [ibm.com]
Einstein-Podolsky-Rosen (EPR) Paradox (Score:3, Informative)
Very good article, but some people might find Einstein-Podolsky-Rosen paradox [wikipedia.org] article on Wikipedia [wikipedia.org] somewhat better for an introductory text, and at the same time richer in details:
The EPR paradox arises in a thought experiment which shows that quantum mechanics leads to
Tsk tsk ... (Score:3, Funny)
And you call yourselves nerds!
So what can't this lead to faster than light? (Score:2)
Now if they want to send a '1' then they entanlge the two photons that they have on thier own end, making all four of them be entangled, and then read just one of them. Now all four of them would be in the same quantum state, no?
This is first (Score:5, Funny)
Re:This is first (Score:5, Funny)
Now is the time to create prior art (Score:3, Funny)
And as long as wide spread adoption of quantum computing is more that 17 years away, companies can't read this message and strike first (prepatenting these ideas first). If companies patent ideas too soon, the patent will be dead when the real money is being made.
Too late (Score:3, Informative)
There are already lots of patents on quantum computing:
5,530,263 [uspto.gov]
5,768,297 [uspto.gov]
6,128,764 [uspto.gov]
6,218,832 [uspto.gov]
and many, many more.
Re:Now is the time to create prior art (Score:4, Interesting)
That's very true, but what I am talking about are the obvious patents, not the ones that require millions of dollars in legitimate investment in R&D. I'm talking about silly little patents that take someone a few hours of thinking and then they try to claim any use of quantum mechanics in some broad area of endeavor (like using qubits to optimize internet routings, or using entanglement to serve ads, or some such "add-a-q-to-any-ordinary-activity" type of patent).
Personally, I am in favor of patents for non-trivial inventions. I wonder if part of the problem with the current patent system is that the examiners may not understand the state of the art well enough to judge which inventions were obvious and which inventions were hard. The point is that easy inventions don't need the encouragement created by a patent -- they will get invented and deployed anyway. Patents should reserved for inventions that could not have happened if the inventor did not think they had a chance of a patent.
It's a separate issue, entirely, whether the fruits of publicly funded research should be patented at all, but that's a different discussion.
Error correction needs a bit more. (Score:3, Informative)
Well, the smallest error correcting code that can protect againt a single error requires five qubits. To actually do error correction you need quite a few more.
I don't think three is enough... (Score:5, Funny)
The Link? (Score:3, Interesting)
I've actually wondered about this in a few QT articles. The picture I get from reading about it, you could entangle photons across the planet and transfer state between them instantly. In many articles, like the one quoted above, they say in one sentence teleportation transfers states without a physical link, but in the next, describe a physical link used in the expirement. Could some quantumly-entangled slashdotter explain this to us unwashed Newtonian masses? Are the "wires" optional?
Re:The Link? (Score:3, Informative)
1) Basically you make some entangles particles (whether they be photons or atoms), and at this point they have an unknown, but equivalent state.
2) You then need to physically transport those particles to different places (by optical fibre, motorbike courier or pack camel)
3) When you read the state of one particle, it forces the particle to choose a state. The other particle also takes on
The RIAA Wants Quantum Computing (Score:5, Funny)
[Scene: RIAA Headquarters]
Mitch Bainwol: "This quadrant teleportation thing sounds too good to be true."
Cary Sherman: "Get me Orrin Hatch on the phone. We need mandatory quantum teleplantation by 2010."
This might be dangerous (Score:3, Insightful)
Hell, it might be decreasing further the chances of nerds getting dates or something
Re:This might be dangerous (Score:3, Insightful)
NonDeterministic Polynomial Time(NP) Class Problem (Score:3, Informative)
Quantum computing will NOT necessarily speed up all your porn browsing, DOOM playing arses. Instead, Quantum computing affects a set of computational problems that fall into the category of "Non-Determinstic time" algorithms. Non-Determinstic algorithms are identifiable by the fact that they all benefit hugely from being run in parallel. Basically a good rule of thumb is that quantum computing will affect algorithms that gain from being run on massive numbers of processors simultaneously given different (but not inter-communicating) inputs.
Some such problems are:
--Most if not all current cryptography
--SETI
--Other problems where you're looking for one specific output given a potentially huge number of inputs.
As an example in cryptography, a sufficiently powerful quantum computer would be able to break your RSA, DSA, DES3 or any other symmetric or non-symmetric cypher instantaneously if the author of the quantum program knew what they were looking for.
I'm suprised no one has mentioned it so far in the threads...
there is an error in the story (Score:3, Informative)
Austria != Australia
In Austria there are NO kangaroos, but the Alps, Mozart, Beethoven, Sissy, Schwarzenegger and the river danube in the middle of europe!
2.)
It should not be "Hans J. Briegal of the Australian Academy of Sciences"
but
"Hans J. Briegel of the Austrian Academy of Sciences"
Read more at the University of Innsbruck/Austria page:
http://homepage.uibk.ac.at/homepage/c705/c705114/ [uibk.ac.at]
A: that's really cool; but... (Score:3, Interesting)
Otherwise wake me when they get as far as transfer booths.
Must go -- gotta teleport some files to the server.
Re:Clarify something to me (Score:4, Interesting)
Re:Quantum... (Score:4, Funny)
In other words, in the time it takes you to transfer a single porn movie, you can simultaneously transmit _every_ porn movie of the same size or less.
Now that's a lot of porn.
Re:This discovery... (Score:3, Interesting)
Re:hopefully a simple question.... (Score:3, Interesting)
Entangled particles are created in a process that conserves quantume properties, like spin. So if a particle is in the spin up state, the other has to be in the spin down state. When they are created, entangled couples are in a undetermined state. As soon as a measurement is made on one of the particles, the other collapse to the complementary state. This happens instantaneously, regardelss of the distance between the particles. However, since you cannot p