Is Time Relative? Understanding Special Relativity

In summary, temperature is a measure of the average heat or thermal energy of particles in a substance, and there is a scale for this known as Kelvin. The laws of thermodynamics and the definition of temperature apply equally across the universe. The theory of relativity, if defined as "the state of being judged in comparison with other things and not by itself," is applied to other aspects of physics and science in general. However, in the context of Einstein’s theories, it has a specific meaning. Physicists have already explored various ideas and thoughts on combining the standard model and general relativity. As for the relation between temperature and relativity, there are interesting discussions and theories on how to define and measure the temperature of an object moving relative
  • #1
Noah332
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What i mean is, for example, the zeroth law of thermodynamics states the if systems A and C are in thermal equilibrium with a system B, then A and C are in thermal equilibrium. Does this mean temperature is relative? Can relativity be applied to other aspects of physics and science in general?
Im just asking this general question.
 
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  • #2
Temperature is a measure of the average heat or thermal energy of particles in a substance. There is a scale - Kelvin - for this, with absolute zero being a theoretical point where there is zero thermal energy (there is no known corresponding maximum temperature that I'm aware of).

So temperature is not 'relative' unless you are comparing items against each other, as your A, B, and C systems suggests.

As far as we can measure, the laws of thermodynamics and the definition of temperature apply equally across the universe.

Now relativity, if defined as "the state of being judged in comparison with other things and not by itself", is applied to other aspects of physics and science in general.

However, relativity, if taken in the context of Einstein’s theories of of Special Relativity and General Relativity, have a very specific meaning that it does not appear that you are referring to, or alluding to, here.
 
  • #3
I see where your getting at, but I am wondering if we rethought about things similar to how Einstein thought of relativity could that change our understanding of the universe and would that make it more easier to combine the standard model and GR?
 
  • #4
Noah332 said:
I see where your getting at, but I am wondering if we rethought about things similar to how Einstein thought of relativity could that change our understanding of the universe and would that make it more easier to combine the standard model and GR?

Physicists have all kinds of thoughts and ideas that they mull over when trying to develop new theories or ways to merge old ones together. I assure you that anything you can think of has already been tried.
 
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  • #5
You may have the wrong idea about what theory of relativity is. Your example with temperatures does not have any relation to the purpose of the theory of relativity. It is not even an example of a "relative" quantity in the common sense of the therm.
 
  • #6
Drakkith said:
Physicists have all kinds of thoughts and ideas that they mull over when trying to develop new theories or ways to merge old ones together. I assure you that anything you can think of has already been tried.

Im sure it has but in case it hasnt I like to ask my questions. Another thought i just had is that since nothing can be colder than absolute zero isn't that the same as nothing can be faster than the speed of light.
 
  • #7
Noah332 said:
Another thought i just had is that since nothing can be colder than absolute zero isn't that the same as nothing can be faster than the speed of light.

No.
 
  • #8
Drakkith said:
No.
Why? Its a physical threshold. What happens if you try to cool something below absolute zero?
 
  • #9
Noah332 said:
Why? Its a physical threshold. What happens if you try to cool something below absolute zero?
Drakkith said:
No.
If you bring the temperature to absolute zero atoms stop moving.

If you move at the speed of light time stops.

Seems similar to me.
 
  • #10
Noah332 said:
If you bring the temperature to absolute zero atoms stop moving.

If you move at the speed of light time stops.

Seems similar to me.

It's an interesting idea. If an object moves relative to you, owing to time dilation the thermal motion of its atoms ought to decrease (relative to you). And, if it gets close to the speed of light relative to you, then it might look like its temperature is close to absolute zero.

There are some interesting things online about how to define and measure the temperature of an object that is moving relative to you. E.g.

https://physics.stackexchange.com/questions/317775/does-temperature-depend-on-velocity-of-observer
You might also ask yourself. If you cool an object and that somehow equates to accelerating the object relative to you, what happens if you heat up an object?
 
  • #11
PeroK said:
It's an interesting idea. If an object moves relative to you, owing to time dilation the thermal motion of its atoms ought to decrease (relative to you). And, if it gets close to the speed of light relative to you, then it might look like its temperature is close to absolute zero.

There are some interesting things online about how to define and measure the temperature of an object that is moving relative to you. E.g.

https://physics.stackexchange.com/questions/317775/does-temperature-depend-on-velocity-of-observer
You might also ask yourself. If you cool an object and that somehow equates to accelerating the object relative to you, what happens if you heat up an object?

That's a very interesting thought. It must slow down in relative terms.
nasu said:
You may have the wrong idea about what theory of relativity is. Your example with temperatures does not have any relation to the purpose of the theory of relativity. It is not even an example of a "relative" quantity in the common sense of the therm.
Temperature is definitely relative. hence the zeroth law of thermodynamics. If, in my example, A and B are in thermal equilibrium but B and C arent then C will feel a temperature difference, hence it would feel if A and B were hot or cold. ie. temperature is relative.
 
  • #12
Noah332 said:
Temperature is definitely relative. hence the zeroth law of thermodynamics. If, in my example, A and B are in thermal equilibrium but B and C arent then C will feel a temperature difference, hence it would feel if A and B were hot or cold. ie. temperature is relative.
Yes, but that has absolutely nothing to do with Einstein's Theory of Relativity (either SR or GR).
 
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  • #13
Noah332 said:
That's a very interesting thought. It must slow down in relative terms.

Temperature is definitely relative. hence the zeroth law of thermodynamics. If, in my example, A and B are in thermal equilibrium but B and C arent then C will feel a temperature difference, hence it would feel if A and B were hot or cold. ie. temperature is relative.

You have a bit of a skewered idea on why a different line of thought appears in science, and in physics in particular.

If you look at Einstein and the history of physics, he came up with the idea of Special Relativity not because he was bored and decided "Hey, what if...?" out of nowhere. There was a very clear impetus for him coming up with the idea because of the problems of Maxwell equations not be covariant under Galilean transformation. In other words, there was a problem at that time, and he was trying to approach it from a different perspective. And then, when he came up with a new idea, he did one very important thing. He showed mathematically that this new idea converges with the old description.

Unfortunately, you never gave a clear impetus for why you'd want to think of temperature having the same "relative" concept. You simply can't invoke "Well, what if... since we already have relativity...", without specifying what exactly is the problem that would be solved if we look at thermodynamics from the different perspective. In other words, what is the worth of our time to delve into this? What does it do? What does it solve? Can it clean windows in record time?

There are infinite number of ideas out there that one can explore. The question is, while it may be interesting, but is it important? Those two criteria are not necessarily mutually inclusive.

Zz.
 
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  • #14
Noah332 said:
That's a very interesting thought. It must slow down in relative terms.

Temperature is definitely relative. hence the zeroth law of thermodynamics. If, in my example, A and B are in thermal equilibrium but B and C arent then C will feel a temperature difference, hence it would feel if A and B were hot or cold. ie. temperature is relative.
nasu said:
You may have the wrong idea about what theory of relativity is. Your example with temperatures does not have any relation to the purpose of the theory of relativity. It is not even an example of a "relative" quantity in the common sense of the therm.
here is another thought that relates to GR, if I take a balloon filled with air, and let's assume this balloon can't pop or melt , and we heat it up from the outside. the balloon will change its geometry in spacetime. If we instead of heating the balloon we pump air in the balloon it will still expand its geometry in spacetime. No? the balloon doesn't know or care how the spacetime around it was affected only that it is now changed.

This idea is similar to Einsteins thought that triggered GR. A man in freefall doesn't feel his own weight.
 
  • #15
ZapperZ said:
You have a bit of a skewered idea on why a different line of thought appears in science, and in physics in particular.

If you look at Einstein and the history of physics, he came up with the idea of Special Relativity not because he was bored and decided "Hey, what if...?" out of nowhere. There was a very clear impetus for him coming up with the idea because of the problems of Maxwell equations not be covariant under Galilean transformation. In other words, there was a problem at that time, and he was trying to approach it from a different perspective. And then, when he came up with a new idea, he did one very important thing. He showed mathematically that this new idea converges with the old description.

Unfortunately, you never gave a clear impetus for why you'd want to think of temperature having the same "relative" concept. You simply can't invoke "Well, what if... since we already have relativity...", without specifying what exactly is the problem that would be solved if we look at thermodynamics from the different perspective. In other words, what is the worth of our time to delve into this? What does it do? What does it solve? Can it clean windows in record time?

There are infinite number of ideas out there that one can explore. The question is, while it may be interesting, but is it important? Those two criteria are not necessarily mutually inclusive.

Zz.
That is true thank you for this.

I am hoping if i put my stupid ideas out to people who know more about the subject than me maybe it will spark some idea in them.

but also, my thoughts are within the realm of relating the standard model and GR. maybe if we rethink things in terms of GR maybe we can combine them in a previously unthought of way. for example according the GR objects of energy change the geometry of spacetime. atoms have energy, why isn't it that they are change the geometry of spacetime around it in a similar way the sun does?
 
  • #16
Noah332 said:
That's a very interesting thought. It must slow down in relative terms.

Temperature is definitely relative. hence the zeroth law of thermodynamics. If, in my example, A and B are in thermal equilibrium but B and C arent then C will feel a temperature difference, hence it would feel if A and B were hot or cold. ie. temperature is relative.

One problem with your idea is that light, which does travel at the speed of light, would be at absolute zero. So, the light from the Sun would cool us down. But, of course, sunlight not only keeps us warm, but ultimatley is the source of all energy on Earth.
 
  • #17
PeroK said:
One problem with your idea is that light, which does travel at the speed of light, would be at absolute zero. So, the light from the Sun would cool us down. But, of course, sunlight not only keeps us warm, but ultimatley is the source of all energy on Earth.
but that's because we don't move at the speed of light. so this change in momentum as the photon particles interact with us cause the appearance of a temperature increase
 
  • #18
Noah332 said:
That is true thank you for this.

I am hoping if i put my stupid ideas out to people who know more about the subject than me maybe it will spark some idea in them.

but also, my thoughts are within the realm of relating the standard model and GR. maybe if we rethink things in terms of GR maybe we can combine them in a previously unthought of way. for example according the GR objects of energy change the geometry of spacetime. atoms have energy, why isn't it that they are change the geometry of spacetime around it in a similar way the sun does?

That still doesn't answer on WHY one would want to do such a thing.

Again, as I've said, it may be "interesting" (to you), but why is it important? What does it solve or make simpler or clearer?

This, you have not clarified.

Zz.
 
  • #19
ZapperZ said:
That still doesn't answer on WHY one would want to do such a thing.

Again, as I've said, it may be "interesting" (to you), but why is it important? What does it solve or make simpler or clearer?

This, you have not clarified.

Zz.
I will have to ponder on this. Thank you
 
  • #20
PeroK said:
One problem with your idea is that light, which does travel at the speed of light, would be at absolute zero. So, the light from the Sun would cool us down. But, of course, sunlight not only keeps us warm, but ultimatley is the source of all energy on Earth.
What I mean is not that light because it moves at the speed of light is cold, its that because light is moving at the speed of light everything around it seems cold. This temperature difference causes us to feel the heat of the light.

Imagine you are a light beam moving from the sun to the earth. your traveling at .9c, time would slow down, hence atoms and molecules around you would inturn slow down. when molecules slow down they become cold. Therefore if you were to slow down time and touch an object it would appear cold.
 
  • #21
Noah332 said:
What I mean is not that light because it moves at the speed of light is cold, its that because light is moving at the speed of light everything around it seems cold. This temperature difference causes us to feel the heat of the light.

Imagine you are a light beam moving from the sun to the earth. your traveling at .9c, time would slow down, hence atoms and molecules around you would inturn slow down. when molecules slow down they become cold. Therefore if you were to slow down time and touch an object it would appear cold.

This is faulty physics that you invented. Light beam does not move at 0.9c. It has to be "c". It is not an arbitrary choice.

And if you think you can transform to light's frame of reference, I'd like you to point out to me what physics you are using to do that, because SR/GR does not allow such a transformation.

Zz.
 
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  • #22
Noah332 said:
What I mean is not that light because it moves at the speed of light is cold, its that because light is moving at the speed of light everything around it seems cold. This temperature difference causes us to feel the heat of the light.

Imagine you are a light beam moving from the sun to the earth. your traveling at .9c, time would slow down, hence atoms and molecules around you would inturn slow down. when molecules slow down they become cold. Therefore if you were to slow down time and touch an object it would appear cold.

You started with an interesting idea and now you are having to reinvent physics and deny experimental facts to support it!

In any case, these forums are for discussing science, not your personal theories about how science ought to be.
 
  • #23
PeroK said:
You started with an interesting idea and now you are having to reinvent physics and deny experimental facts to support it!

In any case, these forums are for discussing science, not your personal theories about how science ought to be.
How do you mean? this isn't about what science ought to be. I haven't reinvented anything. Just think logically. If you slow down time do atoms hold there heat relative to you? If you are standing next to a boiling pot of water and you somehow stopped time, if you touched the boiling water would it feel hot?
 
  • #24
ZapperZ said:
This is faulty physics that you invented. Light beam does not move at 0.9c. It has to be "c". It is not an arbitrary choice.

And if you think you can transform to light's frame of reference, I'd like you to point out to me what physics you are using to do that, because SR/GR does not allow such a transformation.

Zz.
wow dude. ok, so you are traveling at c and time stops. If you are standing next to a boiling pot of water if you touched the boiling water would it feel hot?
 
  • #25
Noah332 said:
wow dude. ok, so you are traveling at c and time stops. If you are standing next to a boiling pot of water if you touched the boiling water would it feel hot?

But that is what I warned you about transforming to the light's reference frame! I told you to watch out for that big hole in the ground, and you still fell into it! (My students will get a chuckle out of that phrase.)

If you are moving at c, what physics did you use? You can't use the consequences predicted by SR, because in SR, the speed of light is ALWAYS "c" in any frame. So again, what physics did you use to be able to describe your world when you're moving at c?

Zz.
 
  • #26
Noah332 said:
How do you mean? this isn't about what science ought to be. I haven't reinvented anything. Just think logically. If you slow down time do atoms hold there heat relative to you? If you are standing next to a boiling pot of water and you somehow stopped time, if you touched the boiling water would it feel hot?

You can't slow down time, you can't stop time. That's your invention. Changes, like heat transfer, require the passage of time.
 
  • #27
ZapperZ said:
But that is what I warned you about transforming to the light's reference frame! I told you to watch out for that big hole in the ground, and you still fell into it! (My students will get a chuckle out of that phrase.)

If you are moving at c, what physics did you use? You can't use the consequences predicted by SR, because in SR, the speed of light is ALWAYS "c" in any frame. So again, what physics did you use to be able to describe your world when you're moving at c?

Zz.
Im talking about if you are moving at the speed of light, forget the light beam for a second and please don't talk down to me. I am trying to just discuss this with people in a nice way. if you disagree please say so and tell me why and let's come to a conclusion together not one where your students chuckle at me.

this is a thought experiment. and if you think logically it makes sense. if you move at the speed of light or close to the speed of light doesn't time slow down? and if time slows down around you wouldn't it make sense that things would feel colder to you?
 
  • #28
Noah332 said:
Im talking about if you are moving at the speed of light
Not possible

if you move at the speed of light or close to the speed of light doesn't time slow down?
Absolutely not.

I suggest you stop posting nonsense and read some actual physics.
 
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  • #29
PeroK said:
You can't slow down time, you can't stop time. That's your invention. Changes, like heat transfer, require the passage of time.
thats Einsteins invention. its called time dilation. In order for the speed of light to remain constant in all inertial frames of reference then time has to be able to slow down. as well as space needs to expand. hence the idea of spacetime and it curving.

"Gravitational time dilation is a form of time dilation, an actual difference of elapsed time between two events as measured by observers situated at varying distances from a gravitating mass. The higher the gravitational potential (the farther the clock is from the source of gravitation), the faster timepasses. "

https://en.wikipedia.org/wiki/Gravitational_time_dilation

when you are near a black hole's event horizon the closer you get the slower time gets.

This is part of GR.
 
  • #31
Noah332 said:
thats Einsteins invention. its called time dilation. In order for the speed of light to remain constant in all inertial frames of reference then time has to be able to slow down. as well as space needs to expand. hence the idea of spacetime and it curving.

"Gravitational time dilation is a form of time dilation, an actual difference of elapsed time between two events as measured by observers situated at varying distances from a gravitating mass. The higher the gravitational potential (the farther the clock is from the source of gravitation), the faster timepasses. "

https://en.wikipedia.org/wiki/Gravitational_time_dilation

when you are near a black hole's event horizon the closer you get the slower time gets.

This is part of GR.
All of this is incorrect. You are confusing time dilation with differential aging due to different paths through spacetime. Yes, if you synchronize two clocks and then move them apart, either having one go deeper into a gravity well or move at a high speed, and then you bring them back together, they will show differnt times. This is NOT "time slowing down" (or speeding up), it is differential aging. EVERYTHING see time move at one second per second, regardless of where it is in a gravity well or how fast it is moving relative to something else.

Your misconception about time changing rates is a very common one, but that doesn't make it right. Again, I suggest you study the actual physics.
 
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  • #33
Noah332 said:
Im talking about if you are moving at the speed of light, forget the light beam for a second and please don't talk down to me. I am trying to just discuss this with people in a nice way. if you disagree please say so and tell me why and let's come to a conclusion together not one where your students chuckle at me.

this is a thought experiment. and if you think logically it makes sense. if you move at the speed of light or close to the speed of light doesn't time slow down? and if time slows down around you wouldn't it make sense that things would feel colder to you?

If you travel close to the speed of light with respect to another reference frame, your clock and time is no different than what it is now! You have not understood SR! Proper time and Proper length remain no different than if you are "not moving"! So no, your time doesn't slow down!

Zz.
 
  • #34
ZapperZ said:
If you travel close to the speed of light with respect to another reference frame, your clock and time is no different than what it is now! You have not understood SR! Proper time and Proper length remain no different than if you are "not moving"! So no, your time doesn't slow down!

Zz.
but time around me has?
 
  • #35
Noah332 said:
but time around me has?
This is really beginning to sound like you are just trolling us. You have been told several times now that there are NO circumstances in which your time "slows down" in your own frame of reference (the time around you).
 
<h2>1. What is special relativity?</h2><p>Special relativity is a theory developed by Albert Einstein in 1905 that explains the relationship between space and time. It states that the laws of physics are the same for all observers in uniform motion, and the speed of light is constant regardless of the observer's frame of reference.</p><h2>2. How does special relativity impact our understanding of time?</h2><p>Special relativity states that time is relative and can be experienced differently by different observers depending on their relative motion. This means that time can appear to pass slower or faster for different observers depending on their velocity.</p><h2>3. What is the concept of time dilation in special relativity?</h2><p>Time dilation is the phenomenon in which time appears to pass slower for an object in motion compared to an object at rest. This is due to the fact that the speed of light is constant, and as an object's velocity increases, time for that object appears to slow down.</p><h2>4. Can time really slow down or speed up?</h2><p>Yes, according to special relativity, time can appear to slow down or speed up for different observers depending on their relative motion. This has been proven through experiments such as the famous Hafele-Keating experiment in which atomic clocks were flown around the world and showed a difference in time when compared to stationary clocks.</p><h2>5. How does special relativity impact our daily lives?</h2><p>Special relativity has a significant impact on our daily lives, as it is the basis for technologies such as GPS, which rely on precise measurements of time to function accurately. It also plays a crucial role in our understanding of the universe and has led to advancements in fields such as astronomy and cosmology.</p>

1. What is special relativity?

Special relativity is a theory developed by Albert Einstein in 1905 that explains the relationship between space and time. It states that the laws of physics are the same for all observers in uniform motion, and the speed of light is constant regardless of the observer's frame of reference.

2. How does special relativity impact our understanding of time?

Special relativity states that time is relative and can be experienced differently by different observers depending on their relative motion. This means that time can appear to pass slower or faster for different observers depending on their velocity.

3. What is the concept of time dilation in special relativity?

Time dilation is the phenomenon in which time appears to pass slower for an object in motion compared to an object at rest. This is due to the fact that the speed of light is constant, and as an object's velocity increases, time for that object appears to slow down.

4. Can time really slow down or speed up?

Yes, according to special relativity, time can appear to slow down or speed up for different observers depending on their relative motion. This has been proven through experiments such as the famous Hafele-Keating experiment in which atomic clocks were flown around the world and showed a difference in time when compared to stationary clocks.

5. How does special relativity impact our daily lives?

Special relativity has a significant impact on our daily lives, as it is the basis for technologies such as GPS, which rely on precise measurements of time to function accurately. It also plays a crucial role in our understanding of the universe and has led to advancements in fields such as astronomy and cosmology.

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