- #106
puzzled fish
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What if it's not destroyed? What if it's the same object coming back and forth in a perfectly closed CTC? How old must it be at a given point on its own CTC? 400? 800? 1200?PAllen said:
What if it's not destroyed? What if it's the same object coming back and forth in a perfectly closed CTC? How old must it be at a given point on its own CTC? 400? 800? 1200?PAllen said:This is where the block universe comes in. If there is one note whose world line begins in 1590, is then passed to your ancestor, then sent back in time, and destroyed in 1590, then it can have only one thing written on it. Shakespeare wrote one thing on it, and that is the only state it has. Whatever Shakespeare's internal perception is, he would effectively ignore the instruction, simply because that is what he did. Block universe erases true free will, which is certainly related to how it implements the chronology protection conjecture.
But yet again, there is no copying. Is there some physical copying going on as you age 1 second? In a CTC, it just happens that two points of the history of an object (which is all forward moving in proper time for the object) are accessible simultaneously for some other frame. THERE IS NO COPYING AT ALL!puzzled fish said:Yes, I've read the timeline again and it seems to me exactly identical to Pallen's answer.
I've explained myself before that a near CTC allows two objects to co-exist, I have no objection to that. My objections is to the making of the copy itself. Copying is a procedure that requires a tremendous amount of interactions with the original object. And suppose that a block-universe is constructed in such a way that past-present is inter-woven in a way as to account for those interactions. I find, macroscopically, the probability that I might be able to reproduce an exact identical copy of a complex object like a book, to be 0 (almost.. very).
By the way, I like post #99 very much. It is like my aging copy example. What do you have to say about this?
puzzled fish said:What if it's not destroyed? What if it's the same object coming back and forth in a perfectly closed CTC? How old must it be at a given point on its own CTC? 400? 800? 1200?
If it's not destroyed, and it is an exact CTC, rather than a near CTC loop back in time for relevant observers, then a thermodynamic anomaly is inherently present. The object achieves an exact microstate it had before. This Is a feature of an exact CTC, and a good reason to be skeptical, but it does not entail any paradox or violation of fundamental laws - the anomly is statistically bizarre, but no micro-laws of physics are violated.puzzled fish said:What if it's not destroyed? What if it's the same object coming back and forth in a perfectly closed CTC? How old must it be at a given point on its own CTC? 400? 800? 1200?
Now, we thoroughly agree. As hard as it is for me, to understand how such things can happen for complex objects, I have to admit that there is always a possibility, although like I said, it's almost nil.PAllen said:If it's not destroyed, and it is an exact CTC, rather than a near CTC loop back in time for relevant observers, then a thermodynamic anomaly is inherently present. The object achieves an exact microstate it had before. This Is a feature of an exact CTC, and a good reason to be skeptical, but it does not entail any paradox or violation of fundamental laws - the anomly is statistically bizarre, but no micro-laws of physics are violated.
puzzled fish said:My objections is to the making of the copy itself.
puzzled fish said:What if it's the same object coming back and forth in a perfectly closed CTC?
puzzled fish said:How old must it be at a given point on its own CTC? 400? 800? 1200?
380 / 2000: You find the printed book in a used book store and buy it.PeterDonis said:I don't understand why, since the making of all the copies in this scenario, as I've already pointed out, is a perfectly mundane process that goes on all the time in our actual world. If you disagree, please point out specifically which copying operation in my timeline you think requires something that is extremely unlikely.
puzzled fish said:380 / 2000: You find the printed book in a used book store and buy it.
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810 / 2000: The printed book is in the vault.
puzzled fish said:you can open the vault in 2000, and corroborate that any differences are owed only due to aging. How likely is that, given that Shakespeare copied the book from his own manuscript that he copied from book #313?
Thank you very much Peter. We are both in agreement now. It can happen... Just very unlikely!PeterDonis said:Neither of these are copying operations. The two copying operations in my timeline are:
0 / 1620: The printed book containing Shakespeare's play is created, using his manuscript of the play as a source.
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401 / 1591: You show Shakespeare the printed book, and he copies out his manuscript of the play from it.
Ah, I see; you are talking, not about how accurate either copying process--book #313 to Shakespeare's manuscript, then Shakespeare's manuscript back to book #313--is in itself, but how accurate their combined result has to be, since it has to be equivalent to a copying operation composed with its exact inverse (because the content of book #313 itself must be unchanged). Yes, I agree this is very unlikely; it's basically a somewhat weakened form of the thermodynamic objection in the exact CTC case. But, as has been pointed out, this doesn't violate any physical laws; it's just statistically very unlikely.
In this imaginary universe I am assuming the speed of light is really, really close to maximum speed, to the point that we couldn't tell the difference with our current technology. Would/could that happen (that is, is such an imaginary universe self-consistent)?PAllen said:If the invariant speed were something different from c, then light would have to have varying speed, in general, either like neutrons or like sound (it would only be c and isotropic in the medium rest frame). Such a universe is conceivable, but it is radically different from ours. The derivations of the Lorentz transform (including the limiting case of Galilean for infinite invariant speed) assuming only isotropy, homogeneity and POR, establish that there can only be one invariant speed.
Battlemage! said:In this imaginary universe I am assuming the speed of light is really, really close to maximum speed, to the point that we couldn't tell the difference with our current technology. Would/could that happen (that is, is such an imaginary universe self-consistent)?
In any event, would such a world have casualty violations?
As phrased, your question is inconsistent because if the speed of light is not exactly equal to the invariant maximum speed ##c##, then its value is necessarily frame-dependent (as are all speeds less than ##c##). Thus, there will exist frames in which light travels at speeds arbitrarily close to zero, and the hypothesis "the speed of light is really, really close to the maximum speed" is ill-formed.Battlemage! said:In this imaginary universe I am assuming the speed of light is really, really close to maximum speed, to the point that we couldn't tell the difference with our current technology. Would/could that happen (that is, is such an imaginary universe self-consistent)?
PAllen said:who wrote the play? No one - it just exists without authorship.
As @Nugatory mentioned, this is not exactly the way to say it, but it is pretty close. The way to say what you want to say "If we were to discover that the photon has some extremely small but non zero mass"Mister T said:If we were to discover that light travels at some speed that's a bit less than the maximum possible speed
Dale said:As @Nugatory mentioned, this is not exactly the way to say it, but it is pretty close. The way to say what you want to say "If we were to discover that the photon has some extremely small but non zero mass"
What I mean in this make believe universe is that there is an invariant speed, but light isn't it. It's just much closer to it than anything else.Nugatory said:As phrased, your question is inconsistent because if the speed of light is not exactly equal to the invariant maximum speed ##c##, then its value is necessarily frame-dependent (as are all speeds less than ##c##). Thus, there will exist frames in which light travels at speeds arbitrarily close to zero, and the hypothesis "the speed of light is really, really close to the maximum speed" is ill-formed.
Battlemage! said:It's just much closer to it than anything else.
But shouldn't that only be a problem if the speed of light is the invariant speed?PeterDonis said:And Nugatory's point is that, if light does not travel at the invariant speed, then how "close" the speed of light (meaning, the actual speed at which light is measured to travel) is to the invariant speed is frame-dependent; there will be frames in which the speed of light is not closer to the invariant speed than the speed of anything else. In fact, there will be frames in which the speed of light is zero--in which light is at rest.
It is a problem for your description of that world: "The speed of light is really close to the invariant velocity". That's why Dale suggested that you think in terms of the photon rest mass instead.Battlemage! said:But shouldn't that only be a problem if the speed of light is the invariant speed?
Well let me ask another question, if you don't mind, so I can better grasp the situation:Nugatory said:It is a problem for your description of that world: "The speed of light is really close to the invariant velocity". That's why Dale suggested that you think in terms of the photon rest mass instead.
I thought as much.Ibix said:You can only see a photon that hits a sensor such as your eye. If you see a laser beam, for example, what you are actually seeing is light scattered from the beam because it's passing through a scattering medium. This is why nightclubs pump in smoke before shining lasers through them. Also why it's always cloudy above Gotham. Batman wouldn't be able to see the bat signal on a clear starry night.
If the universe is Lorentz invariant, then it would be impossible for the speed of light to be "really, really close to the invariant speed", as you were trying to specify. Either it would be exactly the invariant speed or light would work like everything else from snails to bullets to cosmic muons and any number between zero and the invariant speed would be "the speed of light" depending on the frame we choose. The underlying problem is that the phrase "the speed of X" is undefined for all X not moving at the invariant speed; the invariant speed is unique in that you don't have to say what it is relative to.Battlemage! said:I'm not seeing the logical inconsistency if the universe is Lorentz invariant but the speed of light isn't the maximum speed (aside from the fact that Maxwell's equations obviously suggest light as the speed limit). Since this isn't a homework thread, could someone spell it out for a dummy like myself? :)
Ibix said:There isn't one. There is a logical inconsistency if there are two invariant speeds, which tells you that if light does not travel at the invariant speed then it does not have a single defined speed. There is no "speed of the neutron" and there would be no "speed of the photon". That's the point being made here - talking about "the speed of light not being the same as the invariant speed" is slightly wrong because in that case light doesn't have "a" speed, it has many. Better to talk about the photon having zero mass (and traveling at a well defined invariant speed) or non-zero masd (and acting like any other particle).
Ah. When I said light might be really close to the maximum speed in this hypothetical universe, I meant just according to our current measuring devices sitting here at rest in our own frame.Nugatory said:If the universe is Lorentz invariant, then it would be impossible for the speed of light to be "really, really close to the invariant speed", as you were trying to specify. Either it would be exactly the invariant speed or light would work like everything else from snails to bullets to cosmic muons and any number between zero and the invariant speed would be "the speed of light" depending on the frame we choose. The underlying problem is that the phrase "the speed of X" is undefined for all X not moving at the invariant speed; the invariant speed is unique in that you don't have to say what it is relative to.
If you want to describe a universe in which light does not travel at the invariant speed yet is close to the "speed of light is ##c##" universe we think we live in, you would say "a universe in which photons have a very small rest mass".
Sure. Google for "photon mass upper bound" and you'll find some discussion of different ways of calculating the maximum photon mass that would be consistent with current experiments.Battlemage! said:What I'm wondering is the following: IF light wasn't the speed limit, is there a logical scenario where our experiments might not be sensitive enough to tell
The first recorded measurement of the speed of light was made by Galileo in 1638, and he carefully avoided going beyond what his experimental results (at least ten times the speed of sound) supported: "If not instantaneous, it is extraordinarily rapid".For example, in real life I imagine the first attempts to measure the speed of light might have ended with people believing it was infinite.
In a practical sense this would mean that the speed of light emitted by a lamp which you measure in your frame depends on the relative motion between you and the lamp. If you adjust your speed closer and close to that of the lamp, then the speed of the light of this lamp will slower and slower measured in you frame.Battlemage! said:What I'm wondering is the following: IF light wasn't the speed limit, is there a logical scenario where our experiments might not be sensitive enough to tell?
Yes but in practice we wouldn't be able to do that for a long while, which would mean in this hypothetical universe we might not be able to know that light wasn't the maximum speed.timmdeeg said:In a practical sense this would mean that the speed of light emitted by a lamp which you measure in your frame depends on the relative motion between you and the lamp. If you adjust your speed closer and close to that of the lamp, then the speed of the light of this lamp will slower and slower measured in you frame.
ArmChairPhysicist said:for every minute realtime
ArmChairPhysicist said:That which has happened has already passed, that which has not happened doesn't exist, there is only now.
ArmChairPhysicist said:you aren't jumping forward or backward
Battlemage! said:Yes but in practice we wouldn't be able to do that for a long while, which would mean in this hypothetical universe we might not be able to know that light wasn't the maximum speed.
What if, in this strange new universe, the difference is too small to detect? That is, what if the fringe shift in a newer Michaelson-Morley experiment is just too small to detect?timmdeeg said:We would know that the speed of the light isn't invariant, because we have proofed that it depends on relative motion.
Is there a theoretical reason to assume the same propagation velocity of electromagnetic- and gravitational waves?Ibix said:It's still possible that photons do have a very very small mass.