Origin of Universe: Exploring Current Scientific Theories

In summary: God.In summary, scientists do not know how the universe originated from nothing. Some say that it might have been born from regions that were born from other regions, and so on and so forth. Another theory is that quantum vacuum fluctuations could create something from nothing. But no one knows for sure.
  • #36
heldervelez said:
quoting from the link above "Second, the string theorists think of themselves as physicists rather than mathematicians. They believe that their theory describes something real in the physical world. And third, there is not yet any proof that the theory is relevant to physics. The theory is not yet testable by experiment. The theory remains in a world of its own, detached from the rest of physics. String theorists make strenuous efforts to deduce consequences of the theory that might be testable in the real world, so far without success."

To be testable is fundamental to Physics, and this subject can not be avoided.
We can have a bad model, or a not so bad one, or a good one, and thay must be conform to observations to some degree. The good model is more accurate than the others, and possibly some predictions are derived from first principles. The good one as a strong possibility of beeing the simpler.

The String Theory(s) are out of the domain of testability, by its nature, and so are out of the reaml of Physics.

Until now we describe the events in this Universe (the one that is testable) only with simple 3D+time. At least I don't know of any single example that does not fit.

I'm not a specialist in String Theory, and cannot contend about its contents. To remain out of ST is enough that not even its sponsors and specialists can think of a test or prediction.
This topic has been discussed in great detail in many fora, including PF; the questions, puzzles, challenges, issues, etc are not unique to cosmology.

"what's the alternative" ? you ask.
In my opinion the effort must be done in the wave description of matter, the fields they originate and the properties of the space. The actual availability to large particle colliders has leading us to the particle nature of matter, and inhibited the pursue on the wave nature of matter.

As an example of the consequences you can see the post #7 by hellfire and #30 of this thread:
In the 1st equation the assumed gravitacional energy say nothing about fields. Is this ok? I think not. Each particle sets field(s) that evolve in the space. Any work to be done on other particles is to be done by the field.
A mathematician may say that the equations are ok. But physically the reasoning had a bad start.

I do not agree with the formula as of #30 but I agree with the contents that is expressed in bold, and the equation can be reformulated in a more sustainable way.

Another example: in the Particle Physics Forum I put a conceptual problem about https://www.physicsforums.com/showthread.php?t=271606" and, because I mention Fields (without mention to any intervenient particle), I noticed a difficulty by others on the perception of the problem.
That sounds like the beginnings of the basis of some research; good.

As noted in the thread to which you link, and by Chalnoth, a great deal of work has already been done, and many results well-established ... and some of the thorny issues have also been identified.

Wrt cosmology, it would seem at least some work in the 'alternative' you outline has already been done (and published).

IOW, normal science addressing the sorts of puzzles it has been so successful - eventually - tackling for the part several centuries ...
 
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  • #37
heldervelez said:
Well, suppose I am as you say. I have lots of phone calls to make and receive, lot of coordination on my collaborators, prepare the next conference, the anual meeting on special subject XPTO, control if the quantity of papers that my nucleus is producing are enough to guarantee the next annual budget to the department. A colaborator had some idea that I'am afraid of pursue or estimulate because it is non mainstream and I'm an inconfessable fear of become out, to be in is more confortable and pays my check.
Some students are waiting for guidance. And I have a full agenda. I am a specialist of XPTO.
Also I have XXX pappers published, (peer reviewed of course), written Y books about the 'N cagagésimo' of the untestable theory that nobody understands. Everyone applauds and I am a sucess. And I have free access to papers.



-- Now the way I like. My monthly pay check comes regularly and it is ok.
I love physics but I'm unconfortable with the panorama.
I am an amateur in the proper sense of the word (amateur = lover) and I read everything that I can. I am not an specialist, but a generalist and even the non-mainstream theories I' read about (The net as a lot of crackpot). I've not an agenda, and have time to talk to many intelligent guys that I know. I have the net, and access to all papers (that I could not reach because they are paid). May be that way I could find something interesting.
Study Einstein again (not Minkovsky - this is the mathematician), rethink and doubt systematically.

The best time to human thinking was in the classic antiquity (greek time). Lazy times.
To be uncommited to the production is fundamental to reach anything new. Do it for fun, not as an obligation.
Have you read Lee Smolin's book (The Trouble with Physics)?

If so, how does what you would do, on Monday, differ from what Lee does, every Monday?

Or several of the people he mentions?

Or Garrett Lisi*?

People who have thought thoughts outside the nine dots.

People who do not, or did not, have full-time jobs with a university.

People who (apparently) had no trouble getting their non-mainstream ideas published, in relevant peer-reviewed journals.

And who knows? Maybe history will prove that one of them is (was) the next Einstein?

Or maybe that honour will go to Ed Witten?

Why should your ideas on how cosmology, as a science, should be done get any more airtime than anyone else's?

And how is a really smart, objective, disinterested person to decide whose ideas of how cosmology, as a science, should be done have merit?

* who has posted extensively here in PF
 
  • #38
We have to be patient with the pursue of any TOE.
If we don't know how to explain (AFAIK) the http://en.wikipedia.org/wiki/Titius-Bode_law" [Broken] how can we aspire to know the ultimate goal of mankind?

quoting Chalnot "String theory is one attempt to reconcile quantum mechanics and gravity. Loop quantum gravity is another. We don't yet know which, if either, is accurate."

Trying to quantize GR ? Why ?
Photons are quantized not by themselves but because the emiters and receptors are ressonators. In the gravity problem I don't see ressonators.
May be the unification is not possible at all. I wouldn't be chocked.
 
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  • #39
heldervelez said:
Trying to quantize GR ? Why ?
As I said, you end up with unreconcilable contradictions otherwise. The primary problem is that it would mean that an extremely accurate gravitational measurement would allow you to get around the uncertainty principle. So at the very least it must be possible for General Relativity to be such that it can be represented as a superposition of states, so as to accord with the superpositions of states we see in quantum mechanics.

To attempt to illustrate this, imagine that I have a quantum particle (say, a hydrogen atom), prepared in the following state:

|psi> = |0> + |1>

...where |0> is the ground state of the hydrogen atom, and |1> is the first excited state. A hydrogen atom prepared in this superposition of states has no definite energy, and therefore no definite mass.

So what is its gravitational field?
 
  • #40
heldervelez said:
We have to be patient with the pursue of any TOE.
D'accord!

Not least because the maximum particle energies we can investigate in our labs are still some ~9 orders of magnitude (a billion) smaller than those we have observed in cosmic rays (and natural particle accelerators like AGNs may be even more powerful) ... who knows what new physics there will be when we can investigate the vast regions of parameter space that are today terra incognita?

If we don't know how to explain (AFAIK) the http://en.wikipedia.org/wiki/Titius-Bode_law" [Broken] how can we aspire to know the ultimate goal of mankind?
I'm not sure what this has to do with cosmology ...

In any case, it's already likely reasonably well understood (http://fr.arxiv.org/abs/astro-ph/9710116"), and when planetary systems around a large sample of other stars are well characterised, today's theories will have some new data to sink their teeth into.

quoting Chalnot "String theory is one attempt to reconcile quantum mechanics and gravity. Loop quantum gravity is another. We don't yet know which, if either, is accurate."

Trying to quantize GR ? Why ?
Photons are quantized not by themselves but because the emiters and receptors are ressonators. In the gravity problem I don't see ressonators.
May be the unification is not possible at all. I wouldn't be chocked.
Indeed.

Do you now understand why lots of people try to quantise GR?
 
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  • #41
Chalnoth said:
As I said, you end up with unreconcilable contradictions otherwise. The primary problem is that it would mean that an extremely accurate gravitational measurement would allow you to get around the uncertainty principle. So at the very least it must be possible for General Relativity to be such that it can be represented as a superposition of states, so as to accord with the superpositions of states we see in quantum mechanics.

To attempt to illustrate this, imagine that I have a quantum particle (say, a hydrogen atom), prepared in the following state:

|psi> = |0> + |1>

...where |0> is the ground state of the hydrogen atom, and |1> is the first excited state. A hydrogen atom prepared in this superposition of states has no definite energy, and therefore no definite mass.

So what is its gravitational field?

This is a difficult problem. When we can not have a 'definite mass' is different issue as saying that it has no energetic content (mass/energy). Consider a surface apart surrounding your atom. The total energetic content before and after the excitation and any intervenient photon will be in balance and a definite one, nor 0 nor infinite.
In classic mechanics when we have a rope with more than one oscillation in presence we do not desesperate.
When we have to characterize the temperature (say gravity) of a glass of warmed water we will describe it in macroscopical way, not describing the states of all and each particle of water in the glass.
We are seeking the gravity within the 'particle' but perhaps we could find it (or only think of it) only in the space around it as an imprint of some vibration inside the matter.
But I don't feel the need to quantize. Who knows if it is a continual (opposed to quantic) interaction between the space and matter.
 
  • #42
Nereid said:
D'accord!

...
I'm not sure what this has to do with cosmology ...

In any case, it's already likely reasonably well understood (http://fr.arxiv.org/abs/astro-ph/9710116"), and when planetary systems around a large sample of other stars are well characterised, today's theories will have some new data to sink their teeth into.

...
Do you now understand why lots of people try to quantise GR?

Thanks for the link, but I didnt find there an explanation. In another post we can talk about the origin of the Solar System and some difficulties that I have with the accepted model.

I think you are suggesting that the quantity of persons involved and expecting to solve the quantization of GR is proportional to the difficulties (or impossibility I think). As we don't know the answer the effort must be done.
 
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  • #43
heldervelez said:
This is a difficult problem. When we can not have a 'definite mass' is different issue as saying that it has no energetic content (mass/energy). Consider a surface apart surrounding your atom. The total energetic content before and after the excitation and any intervenient photon will be in balance and a definite one, nor 0 nor infinite.
In classic mechanics when we have a rope with more than one oscillation in presence we do not desesperate.
When we have to characterize the temperature (say gravity) of a glass of warmed water we will describe it in macroscopical way, not describing the states of all and each particle of water in the glass.
We are seeking the gravity within the 'particle' but perhaps we could find it (or only think of it) only in the space around it as an imprint of some vibration inside the matter.
But I don't feel the need to quantize. Who knows if it is a continual (opposed to quantic) interaction between the space and matter.
Logically, it is possible that the resolution of the mutual incompatibility between QM and GR could come from removing the 'quantum' component.

However, the experimental validation of QM is astonishing in its breadth and accuracy!

For example, QED, the quantum theory of electromagnetism (which incorporates SR btw) has been tested a dozen ways to Sunday, and all results are within ~2σ of what's expected (from the theory), and the best results match to, what, 14 significant figures.

Further, despite intense efforts, over nearly a century now, no 'hidden value' (or 'hidden variable') theory - in which the HUP is some kind of illusion, for example - has come even close to passing the relevant experimental tests.

IOW, the universe (or reality, or Nature, or whatever you want to call it) really, truly does seem to be 'quantised'.

Oh, and what one feels about any of this stuff - from relativity to quantum mechanics - may be interesting, but it surely isn't science, is it? I mean the resolution of the EPR paradox pretty conclusively shows that naive intuitions are a remarkably unreliable guide, and in the Land of Physics (and Cosmology), Experiment (and Observation) Rules, OK?
 
  • #44
heldervelez said:
Thanks for the link, but I didnt find there an explanation. In another post we can talk about the origin of the Solar System and some difficulties that I have with the accepted model.
Good idea; I look forward to the new thread (in another section of PF).

I think you are suggesting that the quantity of persons involved and expecting to solve the quantization of GR is proportional to the difficulties (or impossibility I think). As we don't know the answer the effort must be done.
Certainly the difficulty of resolving the mutual incompatibility of QM and GR is, in and of itself, an attraction to people who like to work on really, really hard puzzles.

However, another important motivation is that resolving this mutual incompatibility is the most obvious, and biggest, issue to be addressed to do 'new physics' ... oh and it also impinges upon things like the nature of reality, the origin of the universe, and so on ...
 
  • #45
Nereid said:
...
However, the experimental validation of QM is astonishing in its breadth and accuracy!
...
...naive intuitions are a remarkably unreliable guide, and in the Land of Physics (and Cosmology), Experiment (and Observation) Rules, OK?

I agree with you that QM has been successful.
Not only intuitions but also appearances and the obvious things are misleading.
Quoting Einstein ""God is subtle, but he is not malicious"
 
<h2>1. What is the Big Bang Theory?</h2><p>The Big Bang Theory is the most widely accepted scientific explanation for the origin of the universe. It proposes that the universe began as a singularity, a point of infinite density and temperature, and has been expanding and cooling ever since.</p><h2>2. How did the Big Bang happen?</h2><p>The exact cause of the Big Bang is still unknown, but according to the theory, the universe began with a rapid expansion known as inflation. This was followed by the formation of subatomic particles, atoms, and eventually stars and galaxies.</p><h2>3. What evidence supports the Big Bang Theory?</h2><p>There are several pieces of evidence that support the Big Bang Theory, including the observation of the cosmic microwave background radiation, the abundance of light elements, and the redshift of distant galaxies. These observations are consistent with the predictions of the theory.</p><h2>4. Are there other theories about the origin of the universe?</h2><p>Yes, there are other scientific theories about the origin of the universe, such as the Steady State Theory and the Oscillating Universe Theory. However, these theories have been largely discredited or have less evidence supporting them compared to the Big Bang Theory.</p><h2>5. What is the role of dark matter and dark energy in the origin of the universe?</h2><p>Dark matter and dark energy are two of the biggest mysteries in modern cosmology. They are believed to make up a large portion of the universe, but their exact nature and role in the origin of the universe is still not fully understood. Some theories suggest that dark matter played a crucial role in the formation of galaxies and structures in the early universe, while dark energy is thought to be responsible for the current accelerating expansion of the universe.</p>

1. What is the Big Bang Theory?

The Big Bang Theory is the most widely accepted scientific explanation for the origin of the universe. It proposes that the universe began as a singularity, a point of infinite density and temperature, and has been expanding and cooling ever since.

2. How did the Big Bang happen?

The exact cause of the Big Bang is still unknown, but according to the theory, the universe began with a rapid expansion known as inflation. This was followed by the formation of subatomic particles, atoms, and eventually stars and galaxies.

3. What evidence supports the Big Bang Theory?

There are several pieces of evidence that support the Big Bang Theory, including the observation of the cosmic microwave background radiation, the abundance of light elements, and the redshift of distant galaxies. These observations are consistent with the predictions of the theory.

4. Are there other theories about the origin of the universe?

Yes, there are other scientific theories about the origin of the universe, such as the Steady State Theory and the Oscillating Universe Theory. However, these theories have been largely discredited or have less evidence supporting them compared to the Big Bang Theory.

5. What is the role of dark matter and dark energy in the origin of the universe?

Dark matter and dark energy are two of the biggest mysteries in modern cosmology. They are believed to make up a large portion of the universe, but their exact nature and role in the origin of the universe is still not fully understood. Some theories suggest that dark matter played a crucial role in the formation of galaxies and structures in the early universe, while dark energy is thought to be responsible for the current accelerating expansion of the universe.

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