Professional debates about Spacetime

In summary: Copenhagen = Minkowskiinterpretation (where Hilbert space and spacetime are just mathematical tool and subjective).Do you have a reference for this "Minkowski original view" you are describing? Minkowski himself said spacetime was real as soon as he came up with the concept. As far as I know nobody has ever proposed an interpretation of relativity where "spacetime" was just a calculational tool, much less where...
  • #1
lucas_
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Is it not Spacetime is akin to the Wave function in Quantum Mechanics where it is just a mathematical tool and no way to distinguish between different interpretations?

Why is that there are countless professional debates about interpretations of quantum mechanics while there is very few or almost non-existing debates about interpretations of spacetime?

I always tried to wrap my head around spacetime where time is a coordinate and daily visualizing how my passage of time in daily basis is depicted in terms of coordinates and time caused gravity.

Anyone care to give their two cents?
 
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  • #2
lucas_ said:
Is it not Spacetime is akin to the Wave function in Quantum Mechanics where it is just a mathematical tool and no way to distinguish between different interpretations?

What different interpretations are there of spacetime, corresponding to the different interpretations of QM?
 
  • #3
PeterDonis said:
What different interpretations are there of spacetime, corresponding to the different interpretations of QM?

Copenhagen = Block Universe
Many Worlds = LET

Since spacetime interpretation choices are only few.. only two. There are more members of either and so debates are so hot that fighting occurs and I understand why spacetime interpretation is banned here.

In quantum mechanics. Interpretations are many and members are equally divided so less fighting hence not banned.

I'm not discussing about the specific interpretations of spacetime. Just inquiring why are there less professional debates regarding spacetime versus the quantum?
 
  • #4
lucas_ said:
Copenhagen = Block Universe
Many Worlds = LET

If this is meant as an analogy, I don't think it's valid.

lucas_ said:
spacetime interpretation choices are only few.. only two

Those aren't the only two. At the very least, there is a "minimal" interpretation of spacetime that only claims "reality" for what has actually been observed or could have been observed (in other words, what's in the observer's past light cone). That is basically the interpretation I refer to in this Insights article refuting a common argument for the block universe interpretation:

https://www.physicsforums.com/insights/block-universe-refuting-common-argument/
lucas_ said:
why are there less professional debates regarding spacetime versus the quantum?

You would have to ask all the professionals. My own personal take on it is that all of the interpretations of spacetime still tell a reasonably acceptable story, whereas no interpretation of QM does; every QM interpretation requires you to accept something that is very hard to accept. I expand on that some in this Insights article:

https://www.physicsforums.com/insights/fundamental-difference-interpretations-quantum-mechanics/
 
  • #5
PeterDonis said:
If this is meant as an analogy, I don't think it's valid.

Copenhagen - Hilbert space is just a tool to get observable
Block Universe (Minkowski) - Geometry is just a tool to get observation

Many worlds - wave function is real
LET - time dilation or length contraction is physical process

Don't you agree with the analogy. What portion do you think it's not valid?

Those aren't the only two. At the very least, there is a "minimal" interpretation of spacetime that only claims "reality" for what has actually been observed or could have been observed (in other words, what's in the observer's past light cone). That is basically the interpretation I refer to in this Insights article refuting a common argument for the block universe interpretation:

https://www.physicsforums.com/insights/block-universe-refuting-common-argument/You would have to ask all the professionals. My own personal take on it is that all of the interpretations of spacetime still tell a reasonably acceptable story, whereas no interpretation of QM does; every QM interpretation requires you to accept something that is very hard to accept. I expand on that some in this Insights article:

https://www.physicsforums.com/insights/fundamental-difference-interpretations-quantum-mechanics/
 
  • #6
lucas_ said:
Block Universe (Minkowski) - Geometry is just a tool to get observation

This is not at all what the block universe interpretation says. It says that the entire 4-dimensional spacetime is real, not just the part in our past light cone.

lucas_ said:
LET - time dilation or length contraction is physical process

This is not what distinguishes LET from other interpretations. What distinguishes LET is its claim that one particular inertial frame is the "absolute rest" frame, even though there is no way even in principle to find out which one it is.

Btw, you don't need to quote portions of someone else's post that you're not responding to.
 
  • #7
PeterDonis said:
This is not at all what the block universe interpretation says. It says that the entire 4-dimensional spacetime is real, not just the part in our past light cone.

I thought block universe was same as Minkowski original view. So let me correct it.

Different interpretations of QM corresponds to different interpretations in Relativity in the sense of the following:

Copenhagen = Minkowski
interpretation (where Hilbert space and spacetime are just mathematical tool and subjective).

Many Worlds = LET (both objective)

more accurate now?
 
  • #8
lucas_ said:
Minkowski original view.

lucas_ said:
Copenhagen = Minkowski
interpretation (where Hilbert space and spacetime are just mathematical tool and subjective).

Do you have a reference for this "Minkowski original view" you are describing? Minkowski himself said spacetime was real as soon as he came up with the concept. As far as I know nobody has ever proposed an interpretation of relativity where "spacetime" was just a calculational tool, much less where it was subjective.

lucas_ said:
more accurate now?

I don't think so. I think you are simply mistaken about what interpretations of relativity actually say.
 
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  • #9
PeterDonis said:
Do you have a reference for this "Minkowski original view" you are describing? Minkowski himself said spacetime was real as soon as he came up with the concept. As far as I know nobody has ever proposed an interpretation of relativity where "spacetime" was just a calculational tool, much less where it was subjective.

I read it somewhere. I'll dig it up. Before Einstein. Time was a parameter. Separate from space. Now Minkowski made time a coordinate connected to space. This is not natural. Hence is it not spacetime (where space and time are both coordinate) is just calculational tool?
Or should you treat time as coordinate literally? But then is it not like the wave function as tool to get observable only. In relativity. Spacetime is a geometry to get observations only. So only the observable in QM and observations of the geometry in relativity is objective (a relativist in sci.physics onced emphasized relativity was simply geometry).

I don't think so. I think you are simply mistaken about what interpretations of relativity actually say.
 
  • #10
lucas_ said:
Minkowski made time a coordinate connected to space.

No, he made both "space" and "time" coordinates on spacetime.

lucas_ said:
This is not natural.

Why not?

lucas_ said:
is it not spacetime (where space and time are both coordinate) is just calculational tool?

No. Spacetime is a real geometric object. "Space" and "time" are coordinates on it. Just as, for example, a flat sheet of paper is a real geometric object, but you can set up x and y coordinates on it. The coordinates are human calculational tools, but the geometric object itself is not.
 
  • #11
PeterDonis said:
No, he made both "space" and "time" coordinates on spacetime.
Why not?
No. Spacetime is a real geometric object. "Space" and "time" are coordinates on it. Just as, for example, a flat sheet of paper is a real geometric object, but you can set up x and y coordinates on it. The coordinates are human calculational tools, but the geometric object itself is not.

So how does time dilation work? According to relativist Tom Roberts of sci.physics. Spacetime is just geometry. And observations produce reality. So time dilation works because of the geometry.

In your case. Spacetime is a real geometric object and not just geometry? But in our everyday life. Time is time. Space is space. Why should you join them together as coordinates. It's like trying to join cat and dog as coordinates. They don't jibe. If space and time are really coordinates. Why didn't anyone besides Einstein or Minkowski think of it?
 
  • #12
lucas_ said:
time dilation works because of the geometry.

Yes. Time dilation just means the lengths of different paths through spacetime can be different. Just as the lengths of different curves on a piece of paper can be different.

lucas_ said:
in our everyday life. Time is time. Space is space

That's because everyday life does not involve objects with relative velocities close to the speed of light. So we don't observe relativistic effects in everyday life, and it appears to us that time and space can be separated. But as soon as we started doing experiments with objects moving at speeds close to the speed of light, we realized that what appears to us to be true in everyday life is only an approximation.

lucas_ said:
It's like trying to join cat and dog as coordinates. They don't jibe.

Sure they do; just use the speed of light to convert between them. In fact, in relativity, that's what the speed of light is: a conversion factor between space units and time units. And with appropriate choices of those units, the speed of light is 1 and the symmetry between space and time is obvious.
 
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  • #13
PeterDonis said:
Yes. Time dilation just means the lengths of different paths through spacetime can be different. Just as the lengths of different curves on a piece of paper can be different.
That's because everyday life does not involve objects with relative velocities close to the speed of light. So we don't observe relativistic effects in everyday life, and it appears to us that time and space can be separated. But as soon as we started doing experiments with objects moving at speeds close to the speed of light, we realized that what appears to us to be true in everyday life is only an approximation.
Sure they do; just use the speed of light to convert between them. In fact, in relativity, that's what the speed of light is: a conversion factor between space units and time units. And with appropriate choices of those units, the speed of light is 1 and the symmetry between space and time is obvious.

The speed of light is
299,792,458 meters/second.
Space is in meter.
Time is in seconds.

In what sense is the speed of light the conversion factor? Care to show some simple illustration or derivations.

And how could you convert between cat and dog using the speed of light?

thanks to you!
 
  • #14
lucas_ said:
Just inquiring why are there less professional debates regarding spacetime versus the quantum?
Because of the two major interpretations one is simpler, more useful, and more easily generalizable to GR.

Basically, in QM all of the interpretations involve some sort of trade-off. An interpretation that is beneficial for one thing is problematic for another. In contrast, with LET the scientific community sees no clear benefit whereas the block universe has several. In particular, the generalization to GR is an especially strong point.

lucas_ said:
And how could you convert between cat and dog using the speed of light?
This is exceptionally silly. He never claimed it was cats and dogs, that was you. It is not up to him to justify your absurd metaphor.

lucas_ said:
In what sense is the speed of light the conversion factor? Care to show some simple illustration or derivations.
Because that is how it shows up in the math. The spacetime interval is ##ds^=-c^2 dt^2 + dx^2 + dy^2 + dz^2##. This is exactly how conversion factors show up. If you measured x distances in yards and y and z distances in feet then the Euclidean interval would be ##ds^2=3^2dx^2+dy^2+dz^2##

As far as a derivation goes it is a simple exercise to calculate the Lorentz transform of the spacetime interval and show that it is an invariant.
 
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  • #15
lucas_ said:
The speed of light is
299,792,458 meters/second.

In SI units, yes. But those are not the only possible units. Since the speed of light is a universal constant, we can pick units to make its value whatever we want.
 
  • #16
Albert Einstein was not happy with quantum mechanics. Quantum mechanics is much more complex than general relativity. There are lots of ad hoc methods in quantum mechanics, like renormalization. That is the reason why the debate about the philosophy of quantum mechanics will never end.

General relativity, on the other hand, is a classical deterministic theory. It is a lot easier to grasp, in principle. An ugly thing in general relativity is singularities. The theory does not describe how they should behave. Einstein tried to prove that black holes cannot form. Now we know that black holes exist.

The philosophical debate in general relativity, combined with some rudimentary quantum mechanics, concentrates on the inner structure and destiny of black holes and singularities. Since we have no empirical data, the debate will continue indefinitely.
 
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  • #17
lucas_ said:
Don't you agree with the analogy. What portion do you think it's not valid?

That's not how it works. It's your idea. The burden is on you to convince us its right, not on everyone else to show that it's wrong.

I think "Colorless green ideas sleep furiously". Prove me wrong!
 
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  • #18
lucas_ said:
The speed of light is
299,792,458 meters/second.
Space is in meter.
Time is in seconds.

In what sense is the speed of light the conversion factor? Care to show some simple illustration or derivations.

We quite often talk about journeys in terms of time or distance. For example, London to Edinburgh is four hours by train. In that case, the speed of the train is the (approximate) conversion factor.

With light, in vacuum, it is exact: a journey of ##299,792,458m## is exactly ##1s##, with the speed of light as the conversion factor.
 
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  • #19
I should note that there are at least 4 spacetime interpretations that I know of, used by at least some reputable physicists:

Minimalist, as decribed by @PeterDonis
Block universe
LET
EBU (evolving block universe; there is a ‘real’ , possibly fuzzy, boundary between past and future, but it is not conceived in terms of any preferred reference frame. ‘Many fingered time’ is a variant of it. A major proponent of it is George Ellis, coauthor with Steven Hawking of “Large Scale Structure of Spacetime”. One may say that at the end of time it coincides with block universe.)
 
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  • #20
PeterDonis said:
If this is meant as an analogy, I don't think it's valid.
Those aren't the only two. At the very least, there is a "minimal" interpretation of spacetime that only claims "reality" for what has actually been observed or could have been observed (in other words, what's in the observer's past light cone). That is basically the interpretation I refer to in this Insights article refuting a common argument for the block universe interpretation:

https://www.physicsforums.com/insights/block-universe-refuting-common-argument/

The "minimal" interpretation of spacetime clams "reality"
for what has actually been observed or could have been observed, as you described. So it didn't give physical mechanism how exactly space and time produce
time dilation except via the geometry? Just like the "minimal" interpretation of quantum mechanics didn't give mechanism how the wave function was physical? Just trying to see both from a common perspective.

I was looking for an old Discover Einstein anniversary edition (Sept. 2004) magazine which showed how a spinning disc produced curve spacetime. I forgot the details. Do you know of the concept how spinning disc can produce curved spacetime?
 
  • #21
lucas_ said:
it didn't give physical mechanism how exactly space and time produce
time dilation except via the geometry?

Geometry is how spacetime produces time dilation. There is no other physical mechanism. That's true regardless of which interpretation of relativity you adopt; interpretations don't differ at all on this point.

lucas_ said:
"minimal" interpretation of quantum mechanics didn't give mechanism how the wave function was physical

Huh? If the wave function is physical, that's just a basic fact; there is no mechanism that makes it so.
 
  • #22
lucas_ said:
Do you know of the concept how spinning disc can produce curved spacetime?

You need to open a separate thread if you want to ask about this.
 
  • #23
lucas_ said:
Just trying to see both from a common perspective.

And as I've already said, I don't see any such common perspective. The very fact you point out in the OP, that there are endless debates about QM interpretation but not about relativity interpretation, argues against there being such a common perspective.
 
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  • #24
PeterDonis said:
Geometry is how spacetime produces time dilation. There is no other physical mechanism. That's true regardless of which interpretation of relativity you adopt; interpretations don't differ at all on this point.

But in LET, the physical mechanism of time dilation is due to the ether.

Huh? If the wave function is physical, that's just a basic fact; there is no mechanism that makes it so.

Oh. Let's not discuss LET as it is a hated word.
If your reasoning that no other mechanism produces time dilation in other relativity interpretations was true. So.

Geometry is how spacetime produces time dilation. There is no other physical mechanism.

Wave function is how matter produces observable. There is no other physical mechanism.

so Geometry and wave function is space, time, and matter.
 
  • #25
lucas_ said:
Oh. Let's not discuss LET as it is a hated word.
This is fairly disingenuous given the substantive reply I gave you above which you have ignored. It isn’t a hated word, it is simply not a useful concept.
 
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  • #26
lucas_ said:
in LET, the physical mechanism of time dilation is due to the ether

No, it's not, because "being at rest relative to the ether" only maximizes your proper time in a very special set of cases (and which cases they are is in principle unobservable). The ether cannot explain why proper time is ever maximized for an observer who is not at rest relative to the ether--or, since we don't know which inertial frame is actually the ether rest frame, it is better to say that the ether cannot explain why proper time is ever maximized for two different observers who are in relative motion (it's maximized for each observer between a different pair of spacetime events, but that's how it works--you can't just decree that everyone has to only travel between some fixed pair of events).

lucas_ said:
Geometry is how spacetime produces time dilation. There is no other physical mechanism.

Yes, and as I said, this is true for any interpretation of relativity.

lucas_ said:
Wave function is how matter produces observable. There is no other physical mechanism.

But this is only true in some interpretations of QM, not all of them.
 
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  • #27
PeterDonis said:
What different interpretations are there of spacetime, corresponding to the different interpretations of QM?
Well, if you read the philosophical literature of that there's an entire plethora of different interpretations. Of course that's all pretty irrelevant for the physics case. Fortunately spacetime is not so much under public debate as quantum theory, where people much more than in the case of space think that some philocophical issues are of relevance in physics. ;-)).
 
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  • #28
PeterDonis said:
No, it's not, because "being at rest relative to the ether" only maximizes your proper time in a very special set of cases (and which cases they are is in principle unobservable). The ether cannot explain why proper time is ever maximized for an observer who is not at rest relative to the ether--or, since we don't know which inertial frame is actually the ether rest frame, it is better to say that the ether cannot explain why proper time is ever maximized for two different observers who are in relative motion (it's maximized for each observer between a different pair of spacetime events, but that's how it works--you can't just decree that everyone has to only travel between some fixed pair of events).
Yes, and as I said, this is true for any interpretation of relativity.
But this is only true in some interpretations of QM, not all of them.

Since we focus on the minimal interpretations. This explains why we have a hard time coming up with quantum gravity.

For example. Imagine the waves in the water in the beach. Let's say some spots of the waves were the observables in QM. And curvature of the beach was like the manifolds of spacetime. And scientists trying to figure out how to relate the curvature of the beach to some spots of the waves in the ocean. I guess this is our attempt at quantum gravity now?

This is what I meant trying to come up with ways how to view QM and Relativity from different perspective. Just to feel the problem with coming up with quantum gravity. Do you think minimal interpretations can solve quantum gravity? What are the main problems of QG in your opinion?

About LET. We can't distinguish LET by experiments and figure out the ether frame. But who knows if quantum particles can use the ether frame for Bell-like correlations. If Bell's Theorem didn't prove either nonreality or locality wrong. We could junk LET. But with Bell's Theorem and Aspect experiments and all those tests producing positive results. We may need the ether. Hope someone can collect all the important threads about it into some kind of FAQ so readers can just read the FAQ. I understand why it's not allowed for discussions and I won't be discussing if further.
 
  • #29
lucas_ said:
I guess this is our attempt at quantum gravity now?

What you describe doesn't seem to bear much resemblance to either string theory or loop quantum gravity, which are the two main contenders right now.

lucas_ said:
Do you think minimal interpretations can solve quantum gravity?

I don't think the question of how to solve quantum gravity has much, if anything, to do with the question of interpretations of QM.

lucas_ said:
What are the main problems of QG in your opinion?

I see two:

(1) Quantum mechanics and General Relativity seem almost incompatible, so it's really hard to imagine a theory that somehow contains both of them as approximations in appropriate limits.

(2) Gravity is really, really weak to begin with, and any quantum aspects of gravity are much weaker still, so it's really hard to imagine how any putative theory of quantum gravity could make any predictions, over and above the predictions we already have from relativity and quantum mechanics in their respective domains, that could be tested now or in the foreseeable future. It's really hard to develop a theory in the total absence of experimental clues.

lucas_ said:
We can't distinguish LET by experiments and figure out the ether frame. But who knows if quantum particles can use the ether frame for Bell-like correlations.

This is the sort of speculation that PF's policy on LET prohibits.

lucas_ said:
I won't be discussing if further.

Ok.
 
  • #30
PeterDonis said:
What you describe doesn't seem to bear much resemblance to either string theory or loop quantum gravity, which are the two main contenders right now.
I don't think the question of how to solve quantum gravity has much, if anything, to do with the question of interpretations of QM.
I see two:

(1) Quantum mechanics and General Relativity seem almost incompatible, so it's really hard to imagine a theory that somehow contains both of them as approximations in appropriate limits.

(2) Gravity is really, really weak to begin with, and any quantum aspects of gravity are much weaker still, so it's really hard to imagine how any putative theory of quantum gravity could make any predictions, over and above the predictions we already have from relativity and quantum mechanics in their respective domains, that could be tested now or in the foreseeable future. It's really hard to develop a theory in the total absence of experimental clues.

Can you really assume SR, GR as approximately described by Newtonian mechanics, and then include higher-order non-Newtonian correction terms in a power series in ##\frac{1}{c^2}##?

"For empirical purposes, there is no need for General Relativity, for example. Or Special Relativity, for that matter. You can just (as is done in the post-Newtonian expansion) assume that physics is approximately described by Newtonian mechanics, and then include higher-order non-Newtonian correction terms in a power series in ##\frac{1}{c^2}##. Let the terms in that expansion be determined experimentally. There is no need for a theory such as General Relativity that attempts to understand the differences in terms of a concept of curved spacetime."

Reference https://www.physicsforums.com/threa...er-meaning-of-quantum-mechanics.972179/page-6
 
  • #31
lucas_ said:
Can you really assume SR, GR as approximately described by Newtonian mechanics, and then include higher-order non-Newtonian correction terms in a power series in ##\frac{1}{c^2}##?

For many purposes, yes. This is called the post-Newtonian approximation:

https://en.wikipedia.org/wiki/Post-Newtonian_expansion
https://en.wikipedia.org/wiki/Parameterized_post-Newtonian_formalism
A good discussion of this approach, and its "unreasonable effectiveness", is in this paper by Will:

https://arxiv.org/pdf/1102.5192.pdf
The "unreasonable effectiveness" part includes the fact that this method works pretty well for predicting the gravitational wave signatures from black hole mergers, even though a black hole is a case which, intuitively, should not be treatable by this method since the region at and inside the horizon cannot be viewed as simply being a perturbation of flat spacetime (which is the underlying rationale of the approach in the first place).

However, this method does not work for cosmology, which suggests that the real limitation of the approach is not being able to view gravity as a perturbation of flat spacetime, but being able to view it as associated with isolated massive objects separated by large regions of empty space. The universe, globally, cannot be described that way, because the universe as a whole is not an "isolated object" in this sense. So there is at least one domain in which viewing gravity as just Newtonian plus correction terms does not appear to work and a different approach is needed.
 
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  • #32
lucas_ said:
But with Bell's Theorem and Aspect experiments and all those tests producing positive results. We may need the ether.
Absolutely, unequivocally, 100% no. We may use the ether if we wish, but we do not in any way need it.
 
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  • #33
PeterDonis said:
For many purposes, yes. This is called the post-Newtonian approximation:

https://en.wikipedia.org/wiki/Post-Newtonian_expansion
https://en.wikipedia.org/wiki/Parameterized_post-Newtonian_formalism
A good discussion of this approach, and its "unreasonable effectiveness", is in this paper by Will:

https://arxiv.org/pdf/1102.5192.pdf
The "unreasonable effectiveness" part includes the fact that this method works pretty well for predicting the gravitational wave signatures from black hole mergers, even though a black hole is a case which, intuitively, should not be treatable by this method since the region at and inside the horizon cannot be viewed as simply being a perturbation of flat spacetime (which is the underlying rationale of the approach in the first place).

However, this method does not work for cosmology, which suggests that the real limitation of the approach is not being able to view gravity as a perturbation of flat spacetime, but being able to view it as associated with isolated massive objects separated by large regions of empty space. The universe, globally, cannot be described that way, because the universe as a whole is not an "isolated object" in this sense. So there is at least one domain in which viewing gravity as just Newtonian plus correction terms does not appear to work and a different approach is needed.

In Hossenfelder peer reviewed blog site.. there was this interview with the father of loop quantum gravity... https://backreaction.blogspot.com/2019/06/a-conversation-with-lee-smolin-about.html

Or you could have heard from it in the general field about Barbour treating space as fundamental while Smolin treating Time as fundamental and space emergent.

I just want to know what interpretation does this emergent or fundamental time or space thing fall under, and why:

1. Minimalist
2. LET
3. Block Universe
4. New interpretation?
 
  • #34
lucas_ said:
I just want to know what interpretation does this emergent or fundamental time or space thing fall under

And I already responded to that:

PeterDonis said:
I don't think the question of how to solve quantum gravity has much, if anything, to do with the question of interpretations of QM.
 
  • #35
PeterDonis said:
And I already responded to that:

I wasn't asking what interpretation emergent (or fundamental) time or emergent (or fundamental) space fall under in quantum mechanics but in relativistic interpretation like Minimalist, LET or Block Universe.

You mentioned: "
I don't think the question of how to solve quantum gravity has much, if anything, to do with the question of interpretations of QM."

I wasn't asking about interpretations of QM but relativity.
 
<h2>1. What is the concept of spacetime?</h2><p>Spacetime is a fundamental concept in physics that combines the three dimensions of space with the dimension of time. It is a mathematical model that describes the physical universe as a four-dimensional continuum, where all events occur in both space and time.</p><h2>2. How does the theory of relativity relate to spacetime?</h2><p>The theory of relativity, proposed by Albert Einstein, explains the relationship between space and time and how they are affected by gravity. It states that the fabric of spacetime is curved by the presence of massive objects, causing the path of objects to deviate from a straight line.</p><h2>3. Are there any alternative theories to explain spacetime?</h2><p>Yes, there are various alternative theories to explain spacetime, such as loop quantum gravity, string theory, and causal sets. These theories attempt to reconcile the principles of quantum mechanics with the concept of spacetime.</p><h2>4. How do professional debates about spacetime impact our understanding of the universe?</h2><p>Professional debates about spacetime are essential in advancing our understanding of the universe. By challenging existing theories and proposing new ones, scientists can uncover new insights about the nature of space, time, and the universe as a whole.</p><h2>5. What are some current debates in the field of spacetime research?</h2><p>One current debate in the field of spacetime research is the conflict between the theory of relativity and quantum mechanics. Another debate is whether spacetime is continuous or discrete, with some theories proposing that it is made up of tiny, indivisible units.</p>

1. What is the concept of spacetime?

Spacetime is a fundamental concept in physics that combines the three dimensions of space with the dimension of time. It is a mathematical model that describes the physical universe as a four-dimensional continuum, where all events occur in both space and time.

2. How does the theory of relativity relate to spacetime?

The theory of relativity, proposed by Albert Einstein, explains the relationship between space and time and how they are affected by gravity. It states that the fabric of spacetime is curved by the presence of massive objects, causing the path of objects to deviate from a straight line.

3. Are there any alternative theories to explain spacetime?

Yes, there are various alternative theories to explain spacetime, such as loop quantum gravity, string theory, and causal sets. These theories attempt to reconcile the principles of quantum mechanics with the concept of spacetime.

4. How do professional debates about spacetime impact our understanding of the universe?

Professional debates about spacetime are essential in advancing our understanding of the universe. By challenging existing theories and proposing new ones, scientists can uncover new insights about the nature of space, time, and the universe as a whole.

5. What are some current debates in the field of spacetime research?

One current debate in the field of spacetime research is the conflict between the theory of relativity and quantum mechanics. Another debate is whether spacetime is continuous or discrete, with some theories proposing that it is made up of tiny, indivisible units.

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