Could cold-traps in permanently shadowed lunar craters one day become sites for future quantum data centers, giving us yet more reasons to go to space?
Datacenters produce lots of heat. You would quickly "use up the cold" and saturate your ability to radiate away heat.
Also, running a cyocooler on Earth simply isn't expensive enough to justify it.
Also, the Moon's cold traps are important scientific sites, containing a record of billions of years. Hopefully we're not short-sighted enough to bulldoze them for server farms or gas stations....
For all the constant buzz from certain quarters, quantum computing is still more promise than substance. There is a certain class of problems where quantum computing may become valuable, but I haven't seen much to indicate that quantum computing will take over general computing. Of course, some one may announce a breakthrough that changes all that, but I'm not holding my breath.
Loophole-Free Bell Inequality Violation with Superconducting Circuits...Our work demonstrates that non-locality is a viable new resource in quantum information technology realized with superconducting circuits with potential applications in quantum communication, quantum computing and fundamental physics
Quote from: Twark_Main on 12/07/2023 12:35 amDatacenters produce lots of heat. You would quickly "use up the cold" and saturate your ability to radiate away heat.Traditional data centers produce lots of heat -- but do Qubits have to produce lots of heat?
Quote from: Twark_Main on 12/07/2023 12:35 amAlso, running a cyocooler on Earth simply isn't expensive enough to justify it.But there's also all kinds of other noise contamination on Earth, from all the electromagnetic waves we produce.Just as we might like to build a sensitive radio telescope on the Far Side of the Moon shielded from the electromagnetic emissions of Earth, perhaps our quantum computing devices would also similarly function better with less disturbances in remote regions of outer space, at colder temperatures, surrounded by shielding. Project Kuiper in the actual Kuiper Belt?
Quote from: Twark_Main on 12/07/2023 12:35 amAlso, the Moon's cold traps are important scientific sites, containing a record of billions of years. Hopefully we're not short-sighted enough to bulldoze them for server farms or gas stations....The nature preserve around Starbase Boca Chica may also have importance in ecology and wildlife study -- but sometimes we make sacrifices to further our progress in another area.
Anyway, the point stands that making your cooling budget smaller (which this won't do btw) is a lousy reason to build your Amazon Datacenter on top of a World Heritage Site. This idea is as bad as using the Great Pyramid of Cheops to prop up your solar farm so you can save some metal...
but does every spot on the Moon have to be a special heritage place?
Ansible when?!
Quote from: sanman on 12/07/2023 02:02 amAnsible when?!Points.
"There are 1.3 tons of copper and 14,000 screws in our machine, as well as a great deal of physics knowledge and engineering know-how," Wallraff says. He believes that it would in principle be possible to build facilities that overcome even greater distances in the same way. This technology could, for instance, be used to connect superconducting quantum computers over great distances.
Quote from: JohnFornaro on 12/11/2023 01:26 pmQuote from: sanman on 12/07/2023 02:02 amAnsible when?!Points.It seems like an Ansible -- ie. a means of instantaneous communication that's faster-than-light:https://phys.org/news/2023-05-entangled-quantum-circuits-einstein-concept.htmlQuote"There are 1.3 tons of copper and 14,000 screws in our machine, as well as a great deal of physics knowledge and engineering know-how," Wallraff says. He believes that it would in principle be possible to build facilities that overcome even greater distances in the same way. This technology could, for instance, be used to connect superconducting quantum computers over great distances.
Ansible
It is concluded that, Bell’s theorem is false because Bell’s inequalities are trivial mathematical relations that, due to an unsuitable assumption of probability, lack essential connection with the real measuring process of the pertinent experiments.
Nobody's explained to me why two entangled particles, separated by an arbitrary distance do not "communicate". Whatever you "do" to the one particle is "noticed" by the other particle. If the Morse code for SOS is sent from the first particle, cannot the "message" be read by the distant particle?What is it that can't be done? change the first particle? Or read the second particle?Here's a link for the lazy:https://en.wikipedia.org/wiki/Bell_testThis article doesn't include a reference to the 2019 paper above.And the CSHS Inequality? More math than should be allowed by law:https://en.wikipedia.org/wiki/CHSH_inequalityUnfortunately, the experimental setup of Alice, Bob, and Charlie doesn't readily map to the experimental machinery I'm broadly familiar with.I keep hoping/thinking that an ansible is possible in priciple.
No. Like all distant entanglement experiments, data cannot be transmitted. You can observe the state at one end and have knowledge of the state at the other end, but you cannot influence either state without breaking entanglement. i.e. you can observe your bit and see that it is 1 and know that the other bit must be 0, but you cannot use this to communicate because you did not get to choose whether the bit was 1 or 0, it is random which one you observe to start with.
But Ed, in quantum computing you do get to choose whether the bit is 1 or 0, because you're loading your information into the entangled qubits. Quantum computing wouldn't be very useful for computing if we couldn't take information about some problem and load it into the entangled qubits. Nobody wants to watch some "calculator" you can't load your calculation into. The whole purpose of Quantum computing is to compute, and not just sit there serenely. We load information into the entangled qubits, they do a computation, and then we read the results out.
What do you have to say about this paper published in Nature?https://www.nature.com/articles/s41586-023-05885-0QuoteLoophole-Free Bell Inequality Violation with Superconducting Circuits...Our work demonstrates that non-locality is a viable new resource in quantum information technology realized with superconducting circuits with potential applications in quantum communication, quantum computing and fundamental physics
Anyway, people are talking about the idea more and more:https://quantumtantra.blogspot.com/2019/11/quantum-ansible.html
You can't just "set" qubits and have them be entangled. You have to go through a special procedure to entangle two qubits on a quantum computer, and afterwards you don't know if they're zero or one.Entanglement (by definition) requires a qubit to be in a superposition. If you know for sure it's a 1 or a 0, then (by definition) it's not in a quantum superposition.
Furthermore, even if you can solve this problem, you still can't build an ansible. All you'd be doing is transmitting regular bits to Bob, which happens at the speed of light. The only things that "goes FTL" is decoherence, but there's no decoherence if you already know the bit values.
This paper ruled out local hidden variable theories. It does not (and doesn't claim to) build an ansible, or show that one is possible."As of 2015 [i.e. this paper], all Bell tests have found that the hypothesis of local hidden variables is inconsistent with the way that physical systems behave."
Okay, fair enough - but...
Quote from: Twark_Main on 12/17/2023 12:51 pmFurthermore, even if you can solve this problem, you still can't build an ansible. All you'd be doing is transmitting regular bits to Bob, which happens at the speed of light. The only things that "goes FTL" is decoherence, but there's no decoherence if you already know the bit values.In which case, why is the computation output instantly readable within the confines of a short distance, but not at a longer discernably "FTL" distance (ie. a non-local distance)
But from what I remember, local hidden variable theories were postulated to justify being able to determine the outcome of quantum measurements (eg. reading the output of your computation) without violating the "no FTL"/causality stuff.So by ruling out local hidden variables, that experiment is saying causality/"no FTL" can be violated -- ie. there can be FTL.
Quote from: sanman on 12/17/2023 04:22 pmOkay, fair enough - but...Yep, I thought you might go down exactly this road, which is why I wrote the next paragraph. I just wanted you to get an answer to your question.Quote from: sanman on 12/17/2023 04:22 pmQuote from: Twark_Main on 12/17/2023 12:51 pmFurthermore, even if you can solve this problem, you still can't build an ansible. All you'd be doing is transmitting regular bits to Bob, which happens at the speed of light. The only things that "goes FTL" is decoherence, but there's no decoherence if you already know the bit values.In which case, why is the computation output instantly readable within the confines of a short distance, but not at a longer discernably "FTL" distance (ie. a non-local distance)That's not what they mean by "non-local."To a quantum physicist, anything further than the reduced Compton radius is "non-local." It's not about short vs long distances on a human scale.Quote from: sanman on 12/17/2023 04:22 pmBut from what I remember, local hidden variable theories were postulated to justify being able to determine the outcome of quantum measurements (eg. reading the output of your computation) without violating the "no FTL"/causality stuff.So by ruling out local hidden variables, that experiment is saying causality/"no FTL" can be violated -- ie. there can be FTL.Remembered wrong. Happens to the best of us.
But Ed, in quantum computing you do get to choose whether the bit is 1 or 0, because you're loading your information into the entangled qubits.