Point 19 seems to conflate quantum fields with imaginary mass and superluminal particles. As far as I know, tachyonic quantum fields and tachyonic 'particles' are unrelated except for an unfortunate naming convention (historically, tachyonic fields were thought to result in tachyonic particles; the name was kept around even after the mistake had been realized).
Note that tachyonic particles are not very particle-like at all, so I prefer the name 'tachyonic interaction':
Tachyons cannot be properly localized, there's a critical frame where they have no energy, their 'life-time' is space-like, both endpoints of the interaction may have the same (intrinsic) type (absorption-absorption, emission-emission), to name just some of the peculiar properties.
Recami argues (imo convincingly) that you cannot use such tachyons to violate causality.
Point 13 is also somewhat questionable, but this is more of a matter of semantics. While each of the galaxies are at rest (or in free fall, if you prefer), they are not at rest relative to one another according to parallel transport along the light ray (otherwise, there would be no red-shift). This is imo the correct way to handle relative velocities in a general-relativistic setting; the fact that their comoving distance is constant doesn't mean they are at rest in any physically meaningful way, but one can at least argue this point both ways.
> But multiverses are entirely out of keeping with the Ockham's Razor approach to doing science, and constitute more of a popular interpretation of quantum mechanics than a serious physical theory.
The multiverse is not a theory - it's a logical consequence of a simple theory. This claim is logically akin to claiming that the universe is identical to the observable universe, because to propose that matter exists outside of direct observation is a violation of Ockam's Razor.
A better response is that it's completely in keeping with Ockham's Razor, just in terms of number of rules instead of number of things.
For example, in an expanding universe we expect lots of galaxies that we see now to end up beyond the observable horizon in the future. Should we assume they stop existing when they cross that horizon (minimizing # of things) or should we avoid adding an extra rule that removes things that cross out of our horizon?
Many worlds is just quantum physics without collapse. It replaces a rule with a whole lot of things. It is both simpler and more complex than Copenhagen, depending on how you weigh simplicity.
> Is even near (but slower than) light travel possible?
Sure; send yourself as data. ;) Just don't use comcast.
On a less flippant note, in addition to the interstellar dust issue, another fun engineering problem is providing the energy necessary. If you want to send a 50 kilogram person to .99c, you'll have to provide about 4 months worth of the United States current energy production (7 quadrillion btu per month or about 7 exajoules)[1].
Now, if you are wiling to increase your flight time by a factor of ten (reducing yourself to .1 c), you can cut this down to merely 15 days worth of California's total consumption[2]. Mind you, that's just the poor 50 kilogram astronaut. The space shuttle weighed in at 75,000 kilograms (empty). So plan on using about 9 months of the United States energy production capacity for your dinky .1 c.
Given that you'll probably want to STOP once you get where you're going, antimatter engines are probably a prerequisite for relativistic space travel.
One way would be to fire an entangled photon down both ends of fibre optic cable in the middle. On the sending end you could observe/ ignore it, and on reviving end you'd observe it.
We'd have to develop cables capable of preserving the entangled state of light particles, and a beam splitter that's more reliable. You could improve the bandwidth considerably by measuring the polarisation of the particle, even more if you could somehow encapsulate the entangled photon for a given period of time.
> In 1935 Einstein, Podolsky, and Rosen published a thought experiment that seemed to produce a paradox in quantum mechanics, as well as demonstrating that it was incomplete. Their argument used the fact that there can be an apparent instantaneous interaction in the measurement of two separated particles that have been prepared in a certain "entangled" manner. Einstein called it "spooky action at a distance". It has been shown by Eberhard that no information can be passed using this effect; so there is no FTL communication, but the paradox is still very controversial. See the FAQ article The EPR Paradox and Bell's Inequality for more details.
You couldn't use this for communication as there is no way to "set" the spin of an entangled photon. You'd effectively have two receivers for the same random signal but no way to actually influence the signal.
I think there was a HN link a while ago about ideas to use this as a perfectly secure key exchange mechanism for crypto. I don't know how serious this idea is, though.
If this worked you could cut down the travel time by doing this multiple times with the same distance between each node.
However because when you observe the photon it collapses randomly and there is no way to tell if the photon has collapsed before you observed it or for the first time as you are observing it you don't actually have any information on if the other side observed it or not.
A thought I've had about this is that perhaps the speed limit within a universe (299,792,458 m/s in ours) is relative to a constant at its Big Bang moment such as total energy contained or maximum rate of expansion of space-time. If the smallest particles of our universe are smaller universes and our universe is a tiny particle within a larger universe, then the speed limit within each could be different.
This theory would allow FTL travel in a larger universe relative to the speed limit of our universe, but not FTL communication. FTL travel within one universe may be the escape velocity required to enter the next larger universe outside of the origin universe's boundary. But a transmission, originally traveling FTL, sent into a smaller universe may be slowed by its speed limit (similar to light propagating through a non-vacuum medium). In a universe expanding like ours, the transmission would never reach the destination.
The consensus interpretation is that FTL is not possible in normal space, since the speed of something is just another way of looking at how "fast" it travels through time - FTL becomes impossible by definition.
However, there is reason to assume a lot of things may be going on that are not strictly speaking taking place in normal flat space.
The article mentions the expansion of the universe as an example, and that's actually a good point to start. By virtue of the universe expanding, the distance between points grows faster than the speed of light as long as those points are sufficiently far apart. This becomes more interesting when you realize that new space in between these points is being created. Sure, the galaxies traveling on this expanding medium are not actually speeding apart powered by classical movement, but they are nevertheless changing position relative to one another in an interesting way.
In fact, what we're interested in when we talk about FTL is not classical movement at all - what we want is to change positions instead. There are places in nature where we know this is happening right now, for example we do know space can "flow" faster than the speed of light on the far side of event horizons.
So if we abandon the idea that we need to accelerate towards a destination, FTL becomes a broader idea of manipulating spacetime in order to be somewhere in less time than if we had actually flown there at the speed of light. There exist proposals for propulsion systems that go in this direction, for example the "warp drive" ideas that cheat by simply shortening the amount of space a vessel has to travel through. Some of these concepts seem to work in theory, for some definition of work.
The trouble with all these ideas is they need impractical amounts of energy. Which is wasteful, since we only need to bend spacetime for a short while and then return it to its original state behind us, something that works analogous to a catalyst would be much better.
At the most fundamental level though, what we are missing is a way of hacking spacetime. Huge masses and energies are how nature bends it, but ideally we would need some other way of manipulating the fabric of existence directly. This is the reason why drive systems in science fiction all have some kind of yet-unknown mystery substance critical to their function. Given how little we actually know about the basic fabric of the universe, ways of doing these manipulations may well exist. They might not. We most likely won't find out for centuries, if ever.
Until then, we must answer the question so that yes, FTL is most likely possible in theory, but it's not even remotely within our grasp right now. It might never work in practice.
Another observation worth considering: cosmic travel times seem utterly problematic right now because we individually live for extremely short periods of time. Spending a few thousand years in transit is much less worrisome if you're, say, an autonomous machine carrying an AI through the galaxy.
We in the west are a bit too obsessed with moving fast.
What do we call a common trick in fantasy and SF that allows someone or something to move large distances in a short time? Teleportation. Spacetime stays the same, you just move through it very fast, whether physically or electronically.
By contrast, fantasy tales in China, Japan, and Korea, both modern and traditional, often show the protagonists practicing shukuchi [1], a trick that literally means "reduced earth" or "compressed land". Space is shrunk, and then you move through the shrunk space at a normal speed. It's basically warp drive, but imagined at least a thousand years before Star Trek. The guru's eyelashes don't even blow in the wind because, after all, he's just walking at his usual pace.
A change of paradigm indeed opens the door to a lot more possibilities, at least in theory if not in practice.
> The consensus interpretation is that FTL is not possible in normal space
I don't think this really makes sense, because "normal space" is not a well-defined term.
What our current relativistic theories say is that spacetime contains a causal structure marked out by light cones, and nothing can move outside the light cones. In certain spacetimes (like the one that describes our expanding universe), it is possible to assign coordinates to events so that it looks like objects are moving apart "faster than light", but when you look at the light cones in those same coordinates, you can confirm that the objects are still moving inside the light cones.
> new space in between these points is being created
This isn't really part of the physics of the expanding universe; it's an interpretation that some people put on it. There's nothing in the actual math that corresponds to "new space being created".
> space can "flow" faster than the speed of light on the far side of event horizons
This isn't really part of the physics either; it's an interpretation (part of what's often called the "river model" of black holes) that can help with visualization, but again there's nothing in the actual math that corresponds to "space flowing faster than light".
> ways of doing these manipulations may well exist
According to our current theories, any such manipulations would require what is called "exotic matter". There are good physical reasons to think that it is not possible to create exotic matter, especially in the quantities we would need to "hack spacetime" (nice phrase!) on the scales we would want to do it. Given that, I don't think it's fair to say that "FTL is most likely possible in theory"; I would say it's most likely not possible on our best current theories.
Another observation worth considering: cosmic travel times seem utterly problematic right now because we individually live for extremely short periods of time. Spending a few thousand years in transit is much less worrisome if you're, say, an autonomous machine carrying an AI through the galaxy.
Interesting. Especially if the AI can learn and evolve along the way.
>Another observation worth considering: cosmic travel times seem utterly problematic right now because we individually live for extremely short periods of time.
Doesn't relativity "solve" this this problem if we can reach near lightspeed, and don't mind it being a one way trip?
re: point 18: It is quite possible to get around this paradox, if you have absolute time. Absolute time means you can't send a message back in absolute time, which means you can't get 'causal loops'.
[+] [-] cygx|11 years ago|reply
Note that tachyonic particles are not very particle-like at all, so I prefer the name 'tachyonic interaction':
Tachyons cannot be properly localized, there's a critical frame where they have no energy, their 'life-time' is space-like, both endpoints of the interaction may have the same (intrinsic) type (absorption-absorption, emission-emission), to name just some of the peculiar properties.
Recami argues (imo convincingly) that you cannot use such tachyons to violate causality.
Point 13 is also somewhat questionable, but this is more of a matter of semantics. While each of the galaxies are at rest (or in free fall, if you prefer), they are not at rest relative to one another according to parallel transport along the light ray (otherwise, there would be no red-shift). This is imo the correct way to handle relative velocities in a general-relativistic setting; the fact that their comoving distance is constant doesn't mean they are at rest in any physically meaningful way, but one can at least argue this point both ways.
[+] [-] spacehome|11 years ago|reply
The multiverse is not a theory - it's a logical consequence of a simple theory. This claim is logically akin to claiming that the universe is identical to the observable universe, because to propose that matter exists outside of direct observation is a violation of Ockam's Razor.
[+] [-] Strilanc|11 years ago|reply
For example, in an expanding universe we expect lots of galaxies that we see now to end up beyond the observable horizon in the future. Should we assume they stop existing when they cross that horizon (minimizing # of things) or should we avoid adding an extra rule that removes things that cross out of our horizon?
Many worlds is just quantum physics without collapse. It replaces a rule with a whole lot of things. It is both simpler and more complex than Copenhagen, depending on how you weigh simplicity.
[+] [-] dnautics|11 years ago|reply
[+] [-] rwmj|11 years ago|reply
[+] [-] archgoon|11 years ago|reply
Sure; send yourself as data. ;) Just don't use comcast.
On a less flippant note, in addition to the interstellar dust issue, another fun engineering problem is providing the energy necessary. If you want to send a 50 kilogram person to .99c, you'll have to provide about 4 months worth of the United States current energy production (7 quadrillion btu per month or about 7 exajoules)[1].
Now, if you are wiling to increase your flight time by a factor of ten (reducing yourself to .1 c), you can cut this down to merely 15 days worth of California's total consumption[2]. Mind you, that's just the poor 50 kilogram astronaut. The space shuttle weighed in at 75,000 kilograms (empty). So plan on using about 9 months of the United States energy production capacity for your dinky .1 c.
Given that you'll probably want to STOP once you get where you're going, antimatter engines are probably a prerequisite for relativistic space travel.
[1] http://www.eia.gov/totalenergy/
[2] http://www.ecdms.energy.ca.gov/elecbycounty.aspx
[+] [-] adrianN|11 years ago|reply
[+] [-] 3327|11 years ago|reply
[+] [-] pippy|11 years ago|reply
We'd have to develop cables capable of preserving the entangled state of light particles, and a beam splitter that's more reliable. You could improve the bandwidth considerably by measuring the polarisation of the particle, even more if you could somehow encapsulate the entangled photon for a given period of time.
[+] [-] gwern|11 years ago|reply
[+] [-] sgt101|11 years ago|reply
[+] [-] tim333|11 years ago|reply
[+] [-] xg15|11 years ago|reply
I think there was a HN link a while ago about ideas to use this as a perfectly secure key exchange mechanism for crypto. I don't know how serious this idea is, though.
[+] [-] placeybordeaux|11 years ago|reply
However because when you observe the photon it collapses randomly and there is no way to tell if the photon has collapsed before you observed it or for the first time as you are observing it you don't actually have any information on if the other side observed it or not.
[+] [-] placeybordeaux|11 years ago|reply
[deleted]
[+] [-] scobar|11 years ago|reply
This theory would allow FTL travel in a larger universe relative to the speed limit of our universe, but not FTL communication. FTL travel within one universe may be the escape velocity required to enter the next larger universe outside of the origin universe's boundary. But a transmission, originally traveling FTL, sent into a smaller universe may be slowed by its speed limit (similar to light propagating through a non-vacuum medium). In a universe expanding like ours, the transmission would never reach the destination.
[+] [-] Udo|11 years ago|reply
However, there is reason to assume a lot of things may be going on that are not strictly speaking taking place in normal flat space.
The article mentions the expansion of the universe as an example, and that's actually a good point to start. By virtue of the universe expanding, the distance between points grows faster than the speed of light as long as those points are sufficiently far apart. This becomes more interesting when you realize that new space in between these points is being created. Sure, the galaxies traveling on this expanding medium are not actually speeding apart powered by classical movement, but they are nevertheless changing position relative to one another in an interesting way.
In fact, what we're interested in when we talk about FTL is not classical movement at all - what we want is to change positions instead. There are places in nature where we know this is happening right now, for example we do know space can "flow" faster than the speed of light on the far side of event horizons.
So if we abandon the idea that we need to accelerate towards a destination, FTL becomes a broader idea of manipulating spacetime in order to be somewhere in less time than if we had actually flown there at the speed of light. There exist proposals for propulsion systems that go in this direction, for example the "warp drive" ideas that cheat by simply shortening the amount of space a vessel has to travel through. Some of these concepts seem to work in theory, for some definition of work.
The trouble with all these ideas is they need impractical amounts of energy. Which is wasteful, since we only need to bend spacetime for a short while and then return it to its original state behind us, something that works analogous to a catalyst would be much better.
At the most fundamental level though, what we are missing is a way of hacking spacetime. Huge masses and energies are how nature bends it, but ideally we would need some other way of manipulating the fabric of existence directly. This is the reason why drive systems in science fiction all have some kind of yet-unknown mystery substance critical to their function. Given how little we actually know about the basic fabric of the universe, ways of doing these manipulations may well exist. They might not. We most likely won't find out for centuries, if ever.
Until then, we must answer the question so that yes, FTL is most likely possible in theory, but it's not even remotely within our grasp right now. It might never work in practice.
Another observation worth considering: cosmic travel times seem utterly problematic right now because we individually live for extremely short periods of time. Spending a few thousand years in transit is much less worrisome if you're, say, an autonomous machine carrying an AI through the galaxy.
[+] [-] kijin|11 years ago|reply
What do we call a common trick in fantasy and SF that allows someone or something to move large distances in a short time? Teleportation. Spacetime stays the same, you just move through it very fast, whether physically or electronically.
By contrast, fantasy tales in China, Japan, and Korea, both modern and traditional, often show the protagonists practicing shukuchi [1], a trick that literally means "reduced earth" or "compressed land". Space is shrunk, and then you move through the shrunk space at a normal speed. It's basically warp drive, but imagined at least a thousand years before Star Trek. The guru's eyelashes don't even blow in the wind because, after all, he's just walking at his usual pace.
A change of paradigm indeed opens the door to a lot more possibilities, at least in theory if not in practice.
[1] https://en.wikipedia.org/wiki/Shukuchi
[+] [-] pdonis|11 years ago|reply
I don't think this really makes sense, because "normal space" is not a well-defined term.
What our current relativistic theories say is that spacetime contains a causal structure marked out by light cones, and nothing can move outside the light cones. In certain spacetimes (like the one that describes our expanding universe), it is possible to assign coordinates to events so that it looks like objects are moving apart "faster than light", but when you look at the light cones in those same coordinates, you can confirm that the objects are still moving inside the light cones.
> new space in between these points is being created
This isn't really part of the physics of the expanding universe; it's an interpretation that some people put on it. There's nothing in the actual math that corresponds to "new space being created".
> space can "flow" faster than the speed of light on the far side of event horizons
This isn't really part of the physics either; it's an interpretation (part of what's often called the "river model" of black holes) that can help with visualization, but again there's nothing in the actual math that corresponds to "space flowing faster than light".
> ways of doing these manipulations may well exist
According to our current theories, any such manipulations would require what is called "exotic matter". There are good physical reasons to think that it is not possible to create exotic matter, especially in the quantities we would need to "hack spacetime" (nice phrase!) on the scales we would want to do it. Given that, I don't think it's fair to say that "FTL is most likely possible in theory"; I would say it's most likely not possible on our best current theories.
[+] [-] Ono-Sendai|11 years ago|reply
In what sense do you mean that? Can you elaborate?
[+] [-] mathattack|11 years ago|reply
Interesting. Especially if the AI can learn and evolve along the way.
[+] [-] gizmo686|11 years ago|reply
Doesn't relativity "solve" this this problem if we can reach near lightspeed, and don't mind it being a one way trip?
[+] [-] gabriel34|11 years ago|reply
[+] [-] DennisP|11 years ago|reply
[+] [-] Ono-Sendai|11 years ago|reply
[+] [-] pdonis|11 years ago|reply
Which, according to our best current theories, we don't.
[+] [-] aaron695|11 years ago|reply
No.
Pretty simple stuff. No, it is not.
No matter how many sci fi movies tell you other wise. It is not.
Every experiment that comes out saying different is either lying/incompetent or the news reporting on it is lying/incompetent.
Just because you want it to be true does not make it either true or possible.
[+] [-] fixedd|11 years ago|reply
It's also impossible to travel 30mph... Oh, Petroleum!
It's also impossible to go to the moon... Oh, RP-1/LOX!
--
Stop pretending we know everything about the universe when we clearly do not. The best you can claim is "No... with current understanding".
[+] [-] lcfcjs|11 years ago|reply