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Gold Barz
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Because if it is then it could cause problems with causality. Or is it possible but our "laws" are still incomplete?
Yes, faster than light communication would cause major problems with causality. To quote d'Inverno (1992, page 22):Gold Barz said:Because if it is then it could cause problems with causality.
Particles that move faster than the speed of light are called superluminal particles or tachyons. There was some excitement in the 1970s surrounding the possible existence of tachyons, but all attempts to detect them to date have failed. This suggests two likely possibilities: either tachyons do not exist or, if they do, they do not interact with ordinary matter. This would seem to be just as well, for otherwise they could be used to signal back into the past and so would appear to violate causality. For example, it would be possible theoretically to construct a device which sent out a tachyon at a given time and which would trigger a mechanism in the device to blow it up before the tachyon was sent out!
Our 'laws' are definitely incomplete, or science would be at a standstill and we would know everything. That particular law, however, is pretty firmly entrenched. New laws, as they are discovered, don't negate the old ones; they expand upon them. Old theories fall by the wayside all of the time, but it isn't considered a 'law' unless it's inviolable.Gold Barz said:Because if it is then it could cause problems with causality. Or is it possible but our "laws" are still incomplete?
Gold Barz said:Because if it is then it could cause problems with causality. Or is it possible but our "laws" are still incomplete?
No, you can't actually use quantum entanglement to send messages faster than light. With quantum teleportation, you need to send a classical signal (speed of light or slower) between the two locations in order for the quantum state to be correctly "teleported".Yaaks said:Faster than light communication is possilble through Quantum Entanglement, though no one knows how??. The idea of quantum teleportation uses this principle...
True, in the case of quantum entaglement, you are not sending a signal from receptor A to receptor B faster than the speed of light, you are transmitting information about the state of the partner particle at the other receptor faster than the speed of light. If the emitter of the entangled particles is exactly in the center of the path between the receptors of the particles, receptor A "knows" the state of the particle at receptor B in half the time that it would take for a classical transmission between A and B. In this way, receptors A and B can share a bit of information at twice the speed of light. If the receptor A is very close to the emitter and recepter B is 100 times farther away, receptor A would get it's relevant information about the state of the entangled particle at receptor B at about 100 times the speed of light (far before the entangled particle ever gets to B), while receptor B would receive information about the particle at receptor A at just a little faster than the speed of light.JesseM said:No, you can't actually use quantum entanglement to send messages faster than light. With quantum teleportation, you need to send a classical signal (speed of light or slower) between the two locations in order for the quantum state to be correctly "teleported".
Danger said:Our 'laws' are definitely incomplete, or science would be at a standstill and we would know everything. That particular law, however, is pretty firmly entrenched. New laws, as they are discovered, don't negate the old ones; they expand upon them. Old theories fall by the wayside all of the time, but it isn't considered a 'law' unless it's inviolable.
True, in the case of quantum entaglement, you are not sending a signal from receptor A to receptor B faster than the speed of light, you are transmitting information about the state of the partner particle at the other receptor faster than the speed of light.
It really depends on your interpretation of QM. In a hidden-variables interpetation like Bohmian mechanics, it is true that the particles are affecting one another's state faster-than-light. In the http://mist.npl.washington.edu/npl/int_rep/tiqm/TI_toc.html you might say that the measurement of one particle had a backwards-in-time influence on the other's state when the two were created. And the many-worlds interpetation tries to explain everything about entanglement without any FTL or backwards-in-time influences, by way of each observer locally splitting into multiple copies during a measurement and the copies in different locations not being matched up until a signal has had time to pass between them. I came up with a simple example to show how in principle a many-worlds-type interpretation can explain the Bell inequality, although in the actual many-worlds interpretation the relation between probability and "number of copies" is not so clear as in my example:turbo-1 said:True, in the case of quantum entaglement, you are not sending a signal from receptor A to receptor B faster than the speed of light, you are transmitting information about the state of the partner particle at the other receptor faster than the speed of light.
say Bob and Alice are each receiving one of an entangled pair of photons, and their decisions about which spin axis to measure are totally deterministic, so the only "splitting" necessary is in the different possible results of their measurements. Label the three spin axes a, b, and c. If they always find opposite spins when they both measure their photons along the same axis, a local hidden-variables theory would say that if they choose different axes, the probability they get opposite spins must be at least 1/3 (assuming there's no correlation between their choice of which axes to measure and the states of the photons before they make the measurement). The actual probability of finding opposite spins when measuring different axes will depend on the angle between the three axes they choose to measure, but all that's important is that it's less than 1/3, so for the sake of the argument let's say it's 1/4.
So suppose Bob's decision will be to measure along axis a, and Alice's decision will be to measure along axis c. When they do this, suppose each splits into 8 parallel versions, 4 measuring spin + and 4 measuring spin -. Label the 8 Bobs like this:
Bob 1: a+
Bob 2: a+
Bob 3: a+
Bob 4: a+
Bob 5: a-
Bob 6: a-
Bob 7: a-
Bob 8: a-
Similarly, label the 8 Alices like this:
Alice 1: c+
Alice 2: c+
Alice 3: c+
Alice 4: c+
Alice 5: c-
Alice 6: c-
Alice 7: c-
Alice 8: c-
Note that the decision of how they split is based only on the assumption that each has a 50% chance of getting + and a 50% chance of getting - on whatever axis they choose, no knowledge about what the other one was doing was needed. And again, only when a signal traveling at the speed of light or slower passes from one to the other does the universe need to decide which Alice shares the same world with which Bob...when that happens, they can be matched up like this:
Alice 1 (c+) <--> Bob 1 (a+)
Alice 2 (c+) <--> Bob 2 (a+)
Alice 3 (c+) <--> Bob 3 (a+)
Alice 4 (c+) <--> Bob 5 (a-)
Alice 5 (c-) <--> Bob 4 (a+)
Alice 6 (c-) <--> Bob 6 (a-)
Alice 7 (c-) <--> Bob 7 (a-)
Alice 8 (c-) <--> Bob 8 (a-)
This insures that each one has a 3/4 chance of finding out the other got the same spin, and a 1/4 chance that the other got the opposite spin. If Bob and Alice were two A.I.'s running on classical computers in realtime, you could simulate Bob on one computer and Alice on another, make copies of each according to purely local rules whenever each measured a quantum particle, and then use this type of matching rule to decide which of the signals from the various copies of Alice will be passed on to which copy of Bob, and you wouldn't have to make that decision until the information from the computer simulating Alice was actually transmitted to the computer simulating Bob. So using purely local rules you could insure that, after many trials like this, a randomly-selected copy of A.I. Bob or A.I. Alice would record the same type of statistics that's seen in the Aspect experiment, including the violation of Bell's inequality.
Note that you wouldn't have to simulate any hidden variables in this case--you only have to decide what the spin was along the axes each one measured, you never have to decide what the spin along the other 2 unmeasured axes of each photon was.
He doesn't know the state of the other particle, he just knows that if the other experimenter measures along the same axis he did, he'll always get the opposite spin, but if he measures along a different axis, he only knows the probability the other experimenter got the opposite spin, which will be lower than a local hidden-variables theory would lead him to expect. The only difference between the classical case here is that the probabilities are lower than expected if the two experimenters measure different things. For example, suppose I build two boxes which each have three doors behind them, and behind each door is either a black ball or a white ball; I always make sure that if door #1 of the first box has a black ball then door #1 of the second box will have a white ball, and so forth. Also, I install an auto-locking mechanism so as soon as one door is opened the others become impossible to open. Now if I send the two boxes in opposite directions, and you will receive the box in one location at the same time your friend will receive the box at another, then you know that if both you and your friend open the same door of your respective boxes, you will see opposite-colored balls--but obviously this does not involve any FTL information transmission! You also know that if one box contains three white balls and the other contains three black balls, then if you and your friend open different doors, there's a 1/1 chance you'll see opposite colored balls; on the other hand, if your box contains 1 ball of color A and 2 balls of color B, while your friend's contains 2 of color A and 1 of color B, then if you open different doors, the chance you will see opposite colors is (1/3 chance you pick door with color-A ball)*(0/3 chance your friend's door has color-B ball) + (2/3 chance you pick door with color-B ball)*(1/2 chance your friend's door has color-A ball) = 1/3. So if you and your friend pick different doors, then no matter what scheme I used to pick the colors behind each door, a local-hidden-variables theory implies that when you two pick different doors the chance of getting opposite-colored balls must be between 1/3 and 1/1. So if you did this experiment a bunch of times and then got together with your friend to compare notes afterwards, you'd be pretty surprised if, when looking at trials where you both picked different doors, you only found opposite colors on 1/4 of these trials! This is the mystery of entanglement, but you can see that before the two experimenters actually get together to compare notes, the readings of one experimenter don't give her any FTL information about the readings of the other, no more so than in the boxes-with-three-doors experiment.turbo-1 said:If the emitter of the entangled particles is exactly in the center of the path between the receptors of the particles, receptor A "knows" the state of the particle at receptor B in half the time that it would take for a classical transmission between A and B.
That's not quite the same situation. Knowing all of the laws of chess gives one the potential to become a master if other factors don't prevent it. In terms related to your own occupation... someone with a photographic memory can know every law on the books in the world. That gives him the potential to be the best lawyer in the world. If, however, he can't apply them in an intelligent manner he'll never win a case.ohwilleke said:Not true. You can know all the "laws of chess" and still not be a master.
My interpretation of the the difference is that a theory becomes a law when it has proven itself to be unbreakable.ohwilleke said:Also, the line between "theory" and "law" is pretty meaningless. It is more a matter of social convention than any real difference between the two.
Newton's Law of Gravity has been proven unbreakable within the framework to which it applies. You can stand around dropping bricks for the rest of your life and every single one of them is going to hit the ground in accordance with that law. Einsteinian and quantum gravity don't negate that law, they supplement it. Think of them as being like ammendments to your constitution.ohwilleke said:For example, we seek of Newton's Law of Gravity, but Einstein's Theory of General Relativity. We have the theory of evolution, and Murphy's Law (OK that was a cheap shot).
No.ohwilleke said:Also, the line between "theory" and "law" is pretty meaningless. It is more a matter of social convention than any real difference between the two. For example, we seek of Newton's Law of Gravity, but Einstein's Theory of General Relativity. We have the theory of evolution, and Murphy's Law (OK that was a cheap shot).
That distinction doesn't make any sense to me. Are you saying Newtonian gravity is a "law" because it just describes what happens, while General relativity is a "theory" because it describes why? Seems to me that GR just describes what happens too--it doesn't say why matter/energy curves spacetime, or why objects moving in curved spacetime follow geodesic paths, it just says that's what happens, and the predictions you get from this match observations. All of physics is just about mathematical models that make certain predictions, it doesn't deal with meta-explanations of why this model makes accurate predictions but that model doesn't.DaveC426913 said:No.
A law describes something we see; it describes what happens. It is simply a quantified observation.
eg. There is no 'alternate' Law of Gravity. The Law of Gravity simply describes what every scientist on every planet in the universe will jot down on her notepad. They will all describe what speed objects fall and what speed the Moon revolves. Generalizing, they will all arrive at G=(m2*m1)/r^2. It's not negotiable.
OTOH, a theory attempts to describe how or why.
Every one of those scientists on those planets could have a different theory about how/why objects fall or how/why their moon revolves (gravity particles, warped space-time, invisible tendrils), all of which can be negotiated and refuted.
Likewise, Feynman talks about the issue of whether we need a "mechanism" to explain why a particular abstract mathematical theory works in chapter 2 of his book "The Character of Physical Law", which is entitled "The Relation of Mathematics to Physics":10 points for arguing that while a current well-established theory predicts phenomena correctly, it doesn't explain "why" they occur, or fails to provide a "mechanism".
On the other hand, take Newton's law for gravitation, which has the aspects I discussed last time. I gave you the equation:
F=Gmm'/r^2
just to impress you with the speed with which mathematical symbols can convey information. I said that the force was proportional to the product of the masses of two objects, and inversely as the square of the distance between them, and also that bodies react to forces by changing their speeds, or changing their motions, in the direction of the force by amounts proportional to the force and inversely proportional to their masses. Those are words all right, and I did not necessarily have to write the equation. Nevertheless it is kind of mathematical, and we wonder how this can be a fundamental law. What does the planet do? Does it look at the sun, see how far away it is, and decide to calculate on its internal adding machine the inverse of the square of the distance, which tells it how much to move? This is certainly no explanation of the machinery of gravitation! You might want to look further, and various people have tried to look further. Newton was originally asked about his theory--'But it doesn't mean anything--it doesn't tell us anything'. He said, 'It tells you how it moves. That should be enough. I have told you how it moves, not why.' But people are often unsatisfied without a mechanism, and I would like to describe one theory which has been invented, among others, of the type you migh want. This theory suggests that this effect is the result of large numbers of actions, which would explain why it is mathematical.
Suppose that in the world everywhere there are a lot of particles, flying through us at very high speed. They come equally in all directions--just shooting by--and once in a while they hit us in a bombardment. We, and the sun, are practically transparent for them, practically but not completely, and some of them hit. ... If the sun were not there, particles would be bombarding the Earth from all sides, giving little impuleses by the rattle, bang, bang of the few that hit. This will not shake the Earth in any particular direction, because there are as many coming from one side as from the other, from top as from bottom. However, when the sun is there the particles which are coming from that direction are partially absorbed by the sun, because some of them hit the sun and do not go through. Therefore the number coming from the sun's direction towards the Earth is less than the number coming from the other sides, because they meet an obstacle, the sun. It is easy to see that the farther the sun is away, of all the possible directions in which particles can come, a smaller proportion of the particles are being taken out. The sun will appear smaller--in fact inversely as the square of the distance. Therefore there will be an impulse on the Earth towards the sun that varies inversely as the square of the distance. And this will be the result of a large number of very simple operations, just hits, one after the other, from all directions. Therefore the strangeness of the mathematical relation will be very much reduced, because the fundamental operation is much simpler than calculating the inverse of the square of the distance. This design, with the particles bouncing, does the calculation.
The only trouble with this scheme is that it does not work, for other reasons. Every theory that you make up has to be analysed against all possible consequences, to see if it predicts anything else. And this does predict something else. If the Earth is moving, more particles will hit it from in front than from behind. (If you are running in the rain, more rain hits you in the front of the face than in the back of the head, because you are running into the rain.) So, if the Earth is moving it is running into the particles coming towards it and away from the ones that are chasing it from behind. So more particles will hit it from the front than from the back, and there will be a force opposing any motion. This force would slow the Earth up in its orbit, and it certainly would not have lasted the three of four billion years (at least) that it has been going around the sun. So that is the end of that theory. 'Well,' you say, 'it was a good one, and I got rid of the mathematics for a while. Maybe I could invent a better one.' Maybe you can, because nobody knows the ultimate. But up to today, from the time of Newton, no one has invented another theoretical description of the mathematical machinery behind this law which does not either say the same thing over again, or make the mathematics harder, or predict some wrong phenomena. So there is no model of the theory of gravity today, other than the mathematical form.
If this were the only law of this character it would be interesting and rather annoying. But what turns out to be true is that the more we investigate, the more laws we find, and the deeper we penetrate nature, the more this disease persists. Every one of our laws is a purely mathematical statement in rather complex and abstruse mathematics.
...[A] question is whether, when trying to guess new laws, we should use seat-of-the-pants feelings and philosophical principles--'I don't like the minimum principle', or 'I do like the minimum principle', 'I don't like action at a distance', or 'I do like action at a distance'. To what extent do models help? It is interesting that very often models do help, and most physics teachers try to teach how to use models and to get a good physical feel for how things are going to work out. But it always turns out that the greatest discoveries abstract away from the model and the model never does any good. Maxwell's discovery of electrodynamics was made with a lot of imaginary wheels and idlers in space. But when you get rid of all the idlers and things in space the thing is O.K. Dirac discovered the correct laws for relativity quantum mechanics simply by guessing the equation. The method of guessing the equation seems to be a pretty effective way of guessing new laws. This shows again that mathematics is a deep way of expressing nature, and any attempt to express nature in philosophical principles, or in seat-of-the-pants mechanical feelings, is not an efficient way.
It always bothers me that, according to the laws as we understand them today, it takes a computing machine an infinite number of logical operations to figure out what goes on in no matter how tiny a region of space, and no matter how tiny a region of time. How can all that be going on in that tiny space? Why should it take an infinite amount of logic to figure out what one tiny piece of space/time is going to do? So I have often made the hypothesis that ultimately physics will not require a mathematical statement, that in the end the machinery will be revealed, and the laws will turn out to be simple, like the chequer board with all its apparent complexities. But this speculation is of the same nature as those other people make--'I like it', 'I don't like it',--and it is not good to be too prejudiced about these things.
Then why do general relativity's predictions deviate from Newtonian gravity's predictions? For an example, look to the perihelion shift in Mercury's orbit, which cannot be explained by Newton's Law of gravity. Obviously, Newton's laws are wrong if applied to the orbit of Mercury.DaveC426913 said:eg. There is no 'alternate' Law of Gravity. The Law of Gravity simply describes what every scientist on every planet in the universe will jot down on her notepad. They will all describe what speed objects fall and what speed the Moon revolves. Generalizing, they will all arrive at G=(m2*m1)/r^2. It's not negotiable.
Gold Barz said:Because if it is then it could cause problems with causality. Or is it possible but our "laws" are still incomplete?
Danger said:Our 'laws' are definitely incomplete, or science would be at a standstill and we would know everything. That particular law, however, is pretty firmly entrenched. New laws, as they are discovered, don't negate the old ones; they expand upon them. Old theories fall by the wayside all of the time, but it isn't considered a 'law' unless it's inviolable.
I do, and it bothers me as well. That's why I stick to my own definitions in order to keep things a bit clearer in my head. Until someone nails it down precisely, I figure they're as good as anyone else's. (There... I stroked my own ego this time so you don't have to.)marlon said:This kind of discussion bothers me sometimes. I mean, at what point do we decide our laws are incomplete ? What is incomplete ? You see my point ?
With my extremely limited knowledge of physics, and particularly QM, I've always sort of considered 'renormalization' to be cheating. It works, but is it the right approach? From what little I've read of it (keeping in mind that I don't even try to understand the math), it seems as if they just invented an identical but opposite entangled universe in order to force parity in situations where it appears to be violated. (Sort of like having 2 glasses each partially filled with water. If glass 'A' has 20% more than glass 'B', they stick a mirror behind them and say "now glass 'A' and glass 'B2' combined have the same amount as glass 'B' and glass 'A2' combined. Now it's all nice and even.") It grits my gears just a bit without being too intolerable, like having a pimple on your ass.marlon said:Look at renormalization theory in QFT, in order to fit physical reality, we perform some mathematical tricks that are merely interpretative, though mathematically not correct. However, when holding on to such a system, we are ablt to describe the quark behaviour and we are able to describe quasi all atomic phenomena with incredible accuracy.
If you mean what I think by that, then it's how I look at it... beat the hell out the theory until you run out of sticks. If it's still alive, it's a law.marlon said:I say we just need to be pragmatic about this and hold on to the hole falsification process.
DaveC426913 said:No.
A law describes something we see; it describes what happens. It is simply a quantified observation.
eg. There is no 'alternate' Law of Gravity. The Law of Gravity simply describes what every scientist on every planet in the universe will jot down on her notepad. They will all describe what speed objects fall and what speed the Moon revolves. Generalizing, they will all arrive at G=(m2*m1)/r^2. It's not negotiable.
OTOH, a theory attempts to describe how or why.
Every one of those scientists on those planets could have a different theory about how/why objects fall or how/why their moon revolves (gravity particles, warped space-time, invisible tendrils), all of which can be negotiated and refuted.
In fact, I'll boil that down:
A law describes something; a theory tries to explain it.
Well, i say, the fact 'that it works' justifies 'it' being the right approach. know there is lots of discussion on this but i chose for the very pragmatic path. For example, i really see no point in all this QM measurement related problems...I know Vanesch will disagree with me on this. But once again i really do not see the problem here.Danger said:With my extremely limited knowledge of physics, and particularly QM, I've always sort of considered 'renormalization' to be cheating. It works, but is it the right approach?
I am not sure i know what you mean. Are you referring to something like http://www.lbl.gov/abc/wallchart/chapters/05/2.html ?From what little I've read of it (keeping in mind that I don't even try to understand the math), it seems as if they just invented an identical but opposite entangled universe in order to force parity in situations where it appears to be violated.
That is indeed what i meantIf you mean what I think by that, then it's how I look at it... beat the hell out the theory until you run out of sticks. If it's still alive, it's a law.
That is what I am saying, yes.JesseM said:That distinction doesn't make any sense to me. Are you saying Newtonian gravity is a "law" because it just describes what happens, while General relativity is a "theory" because it describes why?
Netwon's law of gravitation doesn't make ANY predictions, it merely describes what we actually observe.JesseM said:Seems to me that GR just describes what happens too--it doesn't say why matter/energy curves spacetime, or why objects moving in curved spacetime follow geodesic paths, it just says that's what happens, and the predictions you get from this match observations. All of physics is just about mathematical models that make certain predictions, it doesn't deal with meta-explanations of why this model makes accurate predictions but that model doesn't.
Sure it makes predictions! It can be used to predict the future trajectory of any object in a gravitational field. Of course this predicted trajectory matches what we actually observe in cases where Newtonian physics is fairly accurate, but then general relativity's predicted trajectories also match what we actually observe in a more general set of cases, like the precession of the perihelion of mercury. Would you say that using Newtonian physics to anticipate the trajectory of a spacecraft or a planet is not a prediction, but that using GR to anticipate the bending of light near a star or the precession of the perihelion of Mercury's orbit is a prediction?DaveC426913 said:Netwon's law of gravitation doesn't make ANY predictions, it merely describes what we actually observe.
The "curvature of space" can just be seen as some abstract mathematical machinery used to calculate the trajectory of objects in the presence of conglomerations of matter/energy, one needn't "believe in" curved spacetime as a real entity unto itself. Similarly, in Newtonian physics we do not directly observe force fields that fill space (or force vectors at any given point in space), and these can also just be seen as bits of abstract mathematical machinery rather than being treated as "real" in some ultimate sense. I see no difference between these cases.DaveC426913 said:We do not observe the curvature of space, it is a model that was made up by man to explain - and predict.
If you are moving faster than the speed of light in one person's reference frame, then it is easy to construct a reference frame in which you are traveling back in time. The quote came from d'Inverno, a well respected special relativity textbook.dgoodpasture2005 said:btw i saw something earlier that someone posted about sending something out that is faster than light and then having a detonator button and destroying it before it was sent out?! speed of light does not propogate time in any way, that is false, just because you are moving extremely fast does not mean time goes in reverse.
dgoodpasture2005 said:ellipse... if me and you are at my house... and i hypothetically have a craft that can travel at 300 times the speed of light... and i leave... and my destination is 300 light years away... and i travel there, and then back, it will take me two years ... i will not come back or get there before i leave.. speed of light in no way propogates time or dismisses FTL travel. I'm glad that your textbook is well respected... but i respect my logic more. Time travel is impossible, and traveling faster than light is not going to make it possible. When i leave to a destination it will still take time, i will just arrive faster.. but not before i left.
In short, for any signal sent FTL in one frame of reference, another frame of reference can be found in which that signal actually traveled backwards in time, thus violating causality in that frame.
Hawking has suggested that while Nature does not abhor a vacuum She may very well abhor a time machine. His calculations indicate that vacuum fluctuations of drastically increasing energy, rather like the audio feedback we experience with a PA system when we bring a microphone too close to the speaker, will arise just as the wormhole connection becomes "timelike".
What you are reading about is Einstein's special theory of relativity. It is counter-intuitive at first, but the good news is it can actually start to make a lot of sense once you convince yourself that Einstein's two postulates ("postulate" is another word for "assumption") are correct. Einstein's two postulates are:dgoodpasture2005 said:okay I've read about half of it... and everything is saying that the speed of light controls time... why does this not make sense to me? If i am watching someone travel at .99c and i am here on Earth and i can look into his ship at a clock inside of his ship, and watch it the whole trip, i'd see exactly how long it would take, and our times would be running the same... would they not? if he is traveling at the speed of light, and his destination is one light year away, and i am able to view his clock from here on Earth the whole time(trip), he will still arrive in a year... and it will also take me a year of observation.. therefore our times are running at exactly the same pace? i don't see where this slowing of time comes into affect... or if i do, i don't see how it makes any sense... especially with that explanation i just gave, our time still runs at the same speed, even relative to each other.
No, according to Einstein's theory of relativity, the speed of light is the maximum speed at which anything can travel in the universe. It is a fundamental limit of the universe and cannot be surpassed.
As mentioned before, the speed of light is a fundamental limit of the universe. It would require an infinite amount of energy to accelerate an object to the speed of light, and even if it were possible, it would violate the laws of physics as we know them.
While nothing can travel faster than the speed of light, there are some phenomena that appear to travel faster than light, such as the expansion of the universe and certain quantum effects. However, these do not violate the speed of light limit, as they are not actual objects moving through space.
At this point in time, there is no known way to bypass the speed of light limit. Scientists continue to explore and research different theories and possibilities, but as of now, it remains a fundamental limit of the universe.
The speed of light limit has significant implications for space travel and communication. It means that traveling to other stars or galaxies will take a very long time, and communication with other civilizations in the universe will also be limited. It also means that time travel to the past is not possible, as it would require faster than light speeds.