Wouldn't The Time Being Relative Be A Product Of Space Curvature Near Mass

In summary, the conversation discusses the concept of time dilation and its relation to gravity. The participants debate whether the observed time difference between two clocks is due to light travel time or the actual effect of gravity. They also bring up examples and equations to support their arguments. Ultimately, the conversation concludes that both factors contribute to time dilation.
  • #1
Sarcastic14
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Now, I know that tittle is messy, so I'm going to explain it as clearly I can. One of the proofs to the fact that time is relative is, as I've heard. Putting one clock on the ground, and another a few feets above it. When these clocks measure time, the one above the ground will do it faster, because, as Einstein says, mass slows time and all that stuff.

But, one day I thought of something that bugged me. I made an awful picture to depict it.
Stuff.png


So, as depicted in the picture, a guy observes two clocks, one above the ground more than the other. But what happens to these photons as they get closer to the Earth, is they are pulled with more force towards it. Therefore the one reaching the upper clock will have less gravitational pull applied to him, and will be more unrestrained, with his trajectory shorter than in the other case. The observer gets this photon faster than the second photon, which hit the clock lower to the ground, which was more pulled by the gravitation, which elongated its road, delaying the time it hit the observer's eye, even if both of the photons hit the clock at the same time.

Wouldn't this delay we see between the clocks be simply the effect gravity has on photons, curving their path and making it get to our eyes shortly after the photon from the higher clock hits it.


Oh, and if I'm terribly wrong at something, please don't hate on me. This was just a random thought that popped into my mind once.

I also want to make it clear that this isn't a "theory" of mine that I've come here to discuss. I've already got a warning for discussing my theories on here, even if it was a misunderstanding.
 
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  • #2
Hi Sarcastic :) Time dilation equations predicts what happens after signal travel times have been taken into account. For example we could start with both clocks at ground level and then move clock 2 up to height X and leave it there for a while and then move clock 2 back to ground level and compare the clocks again when they are both alongside each other. This way delays due to light travel times is insignificant and GR predicts that the clock that remained at ground level will show the least elapsed time. You might argue that because clock 2 has moved and clock 1 has not, that the time differences may be due to the differences in motion. This argument can be eliminated by repeating the experiment with both clocks initially at height X and lowering one to ground level and then raising it back up again. Alternatively you send one clock down to ground level and after a long delay send the second clock to ground level. In all cases the clock that spends the most time nearest the massive body shows the least elapsed time and it is nothing to do with light signal travel times.

Also, trivially in your experiment the light paths from the two clocks could be made equal by careful positioning of the observer and the clocks would still tick at the predicted different rates.
 
  • #3
yuiop said:
Time dilation equations predicts what happens after signal travel times have been taken into account.
I'd say that depends on what equation we are talking about. At first sight dynamic time dilation and gravitational time dilation is different but of course it is not when we consider the equivalence principle.

For instance in the case of gravitational time dilation, it is actually the reduced/increased travel time of light that we consider. For instance an observer far away from a black hole will see the clock of a stationary observer close to the event horizon as standing still, some scientist called it "ancient light" e.g. light that took 'forever' to reach the outside observer due to the gravitational differential and opposite we see that the remote clock from the perspective of the stationary observer near the event horizon seems to go faster.

yuiop said:
For example we could start with both clocks at ground level and then move clock 2 up to height X and leave it there for a while and then move clock 2 back to ground level and compare the clocks again when they are both alongside each other. This way delays due to light travel times is insignificant and GR predicts that the clock that remained at ground level will show the least elapsed time.
Yes and no, again in case of gravitational time dilation during the height differential of the clocks the light travel time difference and differential aging was proportional. So I would consider this effect significant.
 
  • #4
Passionflower said:
For instance in the case of gravitational time dilation, it is actually the reduced/increased travel time of light that we consider. For instance an observer far away from a black hole will see the clock of a stationary observer close to the event horizon as standing still, some scientist called it "ancient light" e.g. light that took 'forever' to reach the outside observer due to the gravitational differential and opposite we see that the remote clock from the perspective of the stationary observer near the event horizon seems to go faster.

I am not convinced that gravitational time dilation is explained by light travel time. Consider this example. A long (2 light second) rod extends from a signaller to an observer. The signaller taps the end of the rod at a rate of once per second and simultaneously flashes a flash light, also at a rate of once per second. After an initial delay of 2 seconds the observer starts to see flashes of light at a rate of once per second. After a longer delay he starts to hear the tapping sound and he hears it at a rate of once per second. The sound signal has a longer delay due to the speed of sound being slower than the speed of light, but the frequency of the signals remains the same despite the differences in signal travel time. You can think of the sound clock as the clock near the black hole. The sound simulates the slow down of the light signal but the delayed transmission rate does not in itself change the frequency of the received signal. A clock low down in a gravitational field really does tick slower (than a clock higher up) and is not an artefact of light signal travel times. Signal travel time is relevant to Doppler shift when the source is moving relative to the receiver because each signal is emitted from a different place, but here we are talking about clocks that are stationary relative to the observer.

Passionflower said:
Yes and no, again in case of gravitational time dilation during the height differential of the clocks the light travel time difference and differential aging was proportional. So I would consider this effect significant.

Not quite sure what you are getting at here. I was proposing only comparing the elapsed times of the clocks when they are stationary and alongside each other at the start and end of each experiment. This eliminates any light travel time difference.

<EDIT> I just thought of a better example. Let us say we had a convoy of Ferraris with cruising at 180 mph and a convoy of heavily laden trucks cruising at 18 mph down the same highway. When they pass point A the Ferraris and the trucks are seen to pass at a rate of once per second. One hundred miles further down the highway at point B we see that the Ferraris pass a second observer at a rate of once per second and the same is true for the trucks. While it is true that the trucks arrive long after the the Ferraris, the frequency of arrival is unchanged by the speed of the vehicles or in the case of gravitational time dilation, by the speed of light signals.
 
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  • #5
yuiop said:
A clock low down in a gravitational field really does tick slower (than a clock higher up) and is not an artefact of light signal travel times.
I am not saying it is an artifact what I am saying is that the time dilation and the change in light travel time are the same thing. Time dilation is always a comparison of at least two clocks and in the case of gravitational time dilation this is dependent on the gravitational potential differential which is equivalent to the light travel time change between going from A to B and B to A (which of course might not even be constant).

yuiop said:
Not quite sure what you are getting at here. I was proposing only comparing the elapsed times of the clocks when they are stationary and alongside each other at the start and end of each experiment. This eliminates any light travel time difference.
My point is that the light travel time difference, e.i. time from A to B and B to A is directly proportional to the difference in time accumulation of the respective clocks.
 
  • #6
Passionflower said:
I am not saying it is an artifact what I am saying is that the time dilation and the change in light travel time are the same thing. Time dilation is always a comparison of at least two clocks and in the case of gravitational time dilation this is dependent on the gravitational potential differential which is equivalent to the light travel time change between going from A to B and B to A (which of course might not even be constant).


My point is that the light travel time difference, e.i. time from A to B and B to A is directly proportional to the difference in time accumulation of the respective clocks.

I am still not getting your point. Are you really claiming that gravitational time dilation can be explained purely in terms of light travel times? Could you be more clear on the thought experiment you have in mind and define A and B?
 
  • #7
yuiop said:
I am still not getting your point. Are you really claiming that gravitational time dilation can be explained purely in terms of light travel times? Could you be more clear on the thought experiment you have in mind and define A and B?
I am saying for gravitational time dilation they are equivalent, in other words the amount of differential aging depends on the difference in light travel time between an observer A and B and B and A.

An stationary observer A far away from a black hole will observe the clock from a stationary observer B close to the event horizon as going slow while B sees observer's A clock going fast. If you take the difference in light travel time between A to B and B to A then there is a direct correspondence with the clock differential.
 
  • #8
Passionflower said:
I am saying for gravitational time dilation they are equivalent, in other words the amount of differential aging depends on the difference in light travel time between an observer A and B and B and A.

An stationary observer A far away from a black hole will observe the clock from a stationary observer B close to the event horizon as going slow while B sees observer's A clock going fast. If you take the difference in light travel time between A to B and B to A then there is a direct correspondence with the clock differential.

The reason that they measure different travel times for the light signals is a consequence of their time dilated clocks and not the other way around. Let us say the gravitational gamma factor of B is 10 times that of A and the round trip time for a light signal from A to B and back to A is 100 seconds, then B will measure the light travel time from B to A and back to B as 10 seconds because B's clock is running 10 times slower than A's clock. If the clocks at A and B were running at the same coordinate rate (which we could arrange by speeding up B's clock by a factor of 10 or invoking a universe where clocks do not actually slow down in a gravitational field ) then they would agree on the round trip light travel times. Simple analysis indicates that the round trip time from A-->B -->A must be the same as B-->A-->B and any difference they measure can only be due to actual gravitational slow down of clocks. There is in fact no difference in light travel times in coordinate terms.

It is however true that light slows down lower in a gravitational field (in coordinate terms) but local observers are not aware of this due to the gravitational time dilation of their clocks. It is interesting to analyse what happens to a light signal as it climbs out of a gravitational well. Let us say that B sends a signal from lower down with a frequency of F and wavelength of W as measured by B. A will measure the signal he detects as having a longer wavelength and a lower frequency by a factor of 10. However in coordinate terms, the frequency of the light remains constant as the photon climbs and they conclude that the frequency changes because of differences in their local clock rates. The wavelength really does increase in coordinate terms. This is unusual because we are used to wavelength increasing as an reciprocal of frequency so an increase in wavelength is inconsistent with a constant frequency because normally the speed of light is a constant, but the coordinate speed of light in a gravitational field is not constant.

The gravitational time dilation of the two clocks will cause them to measure all intervals between non local events as different. For example if they both observe a distant super nova event and A says the interval of peek brightness lasted 100 seconds, then B lower down will say the interval lasted only 10 seconds because B's clock is running 10 times slower. We cannot explain differences in the clock rates of A and B in terms of the light travel time from the super nova. I am really confused about what you are claiming. Are you claiming that it can not be proved that clocks lower down do not actually run slower and that all "apparent gravitational time dilation" can be explained or accounted for simply in terms of light travel times?
 
  • #9
yuiop said:
It is however true that light slows down lower in a gravitational field (in coordinate terms) but local observers are not aware of this due to the gravitational time dilation of their clocks.
Exactly that is why the light travel time change and gravitational time dilation it is the same thing.

yuiop said:
Are you claiming that it can not be proved that clocks lower down do not actually run slower and that all "apparent gravitational time dilation" can be explained or accounted for simply in terms of light travel times?
No, I am not saying that, I am saying the is a direct correspondence between light travel time and time dilation between two stationary points.

Also when we have A and B start at the same point and later come together than in addition to gravitational time dilation we also need to take into account dynamical time dilation, e.g. the SR kind.
 

1. How does space curvature near mass affect the concept of time being relative?

According to Einstein's theory of general relativity, space and time are intertwined and can be affected by the presence of mass. This means that the closer an object is to a massive body, the more it will curve the space around it, leading to a distortion of time. This is known as gravitational time dilation.

2. Is time dilation solely caused by space curvature near mass?

No, time dilation can also be caused by high speeds. According to Einstein's theory of special relativity, time moves slower for an object in motion relative to an observer. This is known as time dilation due to velocity.

3. How does time being relative due to space curvature near mass impact our daily lives?

The effects of time dilation due to space curvature near mass are only noticeable when dealing with extremely large masses, such as black holes or when traveling at high speeds. In our daily lives, the impact is negligible and does not significantly affect our perception of time.

4. Can we measure the effects of time dilation due to space curvature near mass?

Yes, the effects of time dilation have been observed and measured in experiments, such as the Hafele-Keating experiment in 1971. This experiment showed that clocks on planes traveling at high speeds experienced a slight time difference compared to stationary clocks on the ground.

5. Are there any practical applications of understanding time dilation due to space curvature near mass?

Yes, the concept of time dilation is crucial in the field of navigation and communication. GPS satellites, for example, have to account for the effects of time dilation to accurately calculate the position on Earth. Understanding time dilation also helps in studying the properties of black holes and other massive objects in space.

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