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Gear300
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Are time and space independent of an object, or are they properties of an object?
Exploring the Relationship Between Time & Space & Objects
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In summary, the conversation discusses the concept of time and space in relation to objects and whether they are independent or properties of the object. Various experiments are proposed to measure this and it is concluded that the interpretation of the results is subjective, but general relativity predicts that in the absence of significant gravitation, the rest clock and reference clock will remain synchronized.
- #2
Dale
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What do you mean physically. In other words, what kind of experiment could you perform to distinguish the two options?
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Civilized
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Statements about time and space are just statements about measurements of distance and duration, and measurements of distance and duration are reducible to observations of objects.
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Gear300
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There is a space-time distortion felt by objects in motion...but is this effect felt only by the objects in motion or is this distortion extended to local space-time?
- #5
Dale
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Again, what would that look like physically? How would you experimentally tell if the distortion was "felt only by the objects" or "extended to local space-time"?
The reason I ask is because if there is no experiment you can use to determine it then you are asking a philosophical question rather than a physics question. Not that there is anything wrong with philosophical questions, but just to realize that they are different from scientific questions.
The reason I ask is because if there is no experiment you can use to determine it then you are asking a philosophical question rather than a physics question. Not that there is anything wrong with philosophical questions, but just to realize that they are different from scientific questions.
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Gear300
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If time is slowing down for an object traveling at high speeds, and if this is only felt by the moving object, then how would we interpret the situation: would it be that the object is distorting time (time is independent of the object), or is the object's time distorting (time is a property of the object)?
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A.T.
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Gear300 said:
You have to clearly say what you want to measure. For example: You have to identical clocks going at the same rate when placed side by side at rest to the observer. When one clock is moving relative to the observer it is measured by the observer to tick slower than the clock at rest to the observer.
You always need two clocks to define time dilation.
Gear300 said:
Does this interpretation change any measurable quantities? If not: pick the one you like more. Physics doesn't care. My favorite is that the clock advancing in space, advances less in time.
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Dale
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Hi Gear300, let me try and guess what I think you are asking and propose an experiment to measure it. If that is not what you are asking then maybe you can refine or correct the experiment:
Consider 3 identical ideal clocks: the reference clock, the rest clock, and the moving clock. The reference clock and the rest clock are far away from each other, at rest wrt each other, and synchronized via the standard Einstein synchronization procedure. The moving clock is moving inertially at relativistic speeds and passes the rest clock as close as possible without colliding (never coming close to the reference clock). After the moving clock departs, are the rest clock and the reference clock still synchronized?
Is that what you were getting at? If not, can you propose a different experiment?
Consider 3 identical ideal clocks: the reference clock, the rest clock, and the moving clock. The reference clock and the rest clock are far away from each other, at rest wrt each other, and synchronized via the standard Einstein synchronization procedure. The moving clock is moving inertially at relativistic speeds and passes the rest clock as close as possible without colliding (never coming close to the reference clock). After the moving clock departs, are the rest clock and the reference clock still synchronized?
Is that what you were getting at? If not, can you propose a different experiment?
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- #9
diazona
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Nice post DaleSpam 
- #10
atyy
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In special relativity, you can move objects around without changing the properties of spacetime (metric). So different positions of objects correspond to the same spacetime.
In general relativity, different positions of objects correspond to different spacetimes.
In both cases, the properties of spacetime are inferred by using objects.
In general relativity, different positions of objects correspond to different spacetimes.
In both cases, the properties of spacetime are inferred by using objects.
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Gear300
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DaleSpam said:
Yes...you have it more or less on the spot...but, based on the other posts, I'm assuming this is left to little more than interpretation?
- #12
diazona
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In the experiment DaleSpam came up with, special relativity predicts that the rest clock and the reference clock would still be synchronized after the moving clock departs.
That entails ignoring gravity, of course, since special relativity doesn't deal with gravity. If you take into account the gravitational forces that the clocks exert on each other, then general relativity predicts that the rest clock and the reference clock would not quite be synchronized. The rest clock would be slightly behind the reference clock due to gravitational time dilation. But that would occur even if the moving clock were sitting still - it's due to the moving clock's mass, not its motion.
That entails ignoring gravity, of course, since special relativity doesn't deal with gravity. If you take into account the gravitational forces that the clocks exert on each other, then general relativity predicts that the rest clock and the reference clock would not quite be synchronized. The rest clock would be slightly behind the reference clock due to gravitational time dilation. But that would occur even if the moving clock were sitting still - it's due to the moving clock's mass, not its motion.
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Dale
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Relativity makes definite predictions about this experiment, how you choose to interpret the prediction is up to you. Provided there is no significant gravitation, the rest clock and the reference clock remain synchronized. If the moving clock is attached to a gravitating mass then the clocks will not remain synchronized.
EDIT: I see that diazona was quicker
EDIT: I see that diazona was quicker
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Gear300
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I see...Thanks for the replies.
FAQ: Exploring the Relationship Between Time & Space & Objects
How does time affect the relationship between space and objects?
Time is a fundamental aspect of the universe and plays a crucial role in the relationship between space and objects. Time determines the movement of objects through space, as well as the changes that occur in the arrangement of objects in space. Additionally, the concept of time dilation, as described by Einstein's theory of relativity, suggests that the passage of time can vary depending on an object's speed and proximity to massive objects.
Are there any theories that attempt to explain the relationship between time, space, and objects?
Yes, there are several theories that attempt to explain the relationship between time, space, and objects. Some of the most notable ones include Einstein's theory of relativity, which explains how time and space are interconnected, and quantum mechanics, which explores the behavior of particles in space and time. Other theories, such as string theory and loop quantum gravity, also attempt to explain the relationship between time, space, and objects on a more fundamental level.
Can objects exist outside of the constraints of time and space?
It is currently unknown if objects can exist outside of the constraints of time and space. Some theories, such as the concept of a multiverse, suggest that there may be other dimensions or universes that exist outside of our own space and time. However, these are still theoretical and have not been proven. In our current understanding of the universe, time and space are fundamental aspects that cannot be separated from objects.
How does gravity affect the relationship between time, space, and objects?
Gravity is a force that affects the relationship between time, space, and objects. According to Einstein's theory of general relativity, gravity is not a force but rather a curvature of space and time caused by the presence of massive objects. This means that gravity can influence the way objects move through space and can also impact the passage of time. For example, time moves slower in areas with stronger gravitational forces, such as near black holes.
How do scientists study the relationship between time, space, and objects?
Scientists use a variety of methods to study the relationship between time, space, and objects. These include conducting experiments, making observations, and using mathematical models and simulations. Scientists also use advanced technologies, such as telescopes and particle accelerators, to gather data and test their theories. Additionally, collaboration and exchange of ideas among scientists in different fields, such as physics and astronomy, are crucial in furthering our understanding of this complex relationship.