Cosmology: Exploring Mainstream Theories & Problems

In summary, George Ellis, a respected cosmologist, has identified several basic problems with mainstream theories in cosmology. These include the reliance on unproven concepts such as inflation, dark matter, and dark energy, as well as the assumption of a flat universe without proper investigation into the curvature of space. He argues that it is the job of cosmologists to accurately measure and determine these parameters rather than simply assuming them to be true.
  • #1
wolram
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What are the (basic) problems with main stream theories of cosmology ?
i do not want crackpotery, just what the people who work in or around
the field think.
I am unqualified to comment and will not, i hope moderators will keep this thead to the point.
 
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  • #2
Basic problems with common professional-grade cosmology

wolram said:
What are the (basic) problems with main stream theories of cosmology ?
...

A wise and thoughtful cosmologist like George Ellis can look at his own field (with experience of many years working in it) and try to say what are the basic problems and unresolved issues.

Ellis was asked to do this recently, by Jeremy Butterfield and John Earman, as a contribution to a book that Butterfield and Earman are editing.

Here is what he contributed
http://arxiv.org/abs/astro-ph/0602280

There are several ways to respond to your question Wolram, one way would be to try to think of reasons why the whole field of cosmology is no damn good and totally off track---and maybe fundamentally incapable of usefully adding to human knowledge. I would not respond that way myself.

Another way is more like Ellis which is a very constructive moderate criticism saying what have we possibly got wrong that we might fix, and what are some major things we arent certain about but could study and get more certain.

If you want, I will sift thru Ellis essay and quote a few things he says.
If that is to your purpose.

the whole essay is not critical of cosmology. It is focused on the philosophical questions, but whenever anyone does an analysis of the philosophical issues of a field it is necessarily going to involve identifying areas of shallowness and uncertainty, so if the writer does a thorough job it will contain criticism.
 
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  • #3
The mainstream cosmological model fits very well and is compelling to those who study it.

Astrophysics is the application of physics discovered 'down here' to the universe 'out there'. Cosmology is the extension of that discipline to the largest possible scales.

The major theory of local physics that applies on a cosmological scale is GR. It has been well tested in the solar system but there are a few questions about the cosmological model it produces: It has required the invocation of Inflation, DM and DE whereas none of these have been discovered or verified in a laboratory 'down here'. They all might be positively identified, and their properties found to be concordant, tomorrow, but it hasn't happened yet. Various Higgs Boson/Inflaton/DM particles are thrown up by theoretical particle physics, but yet again they are at the moment only hypothetical particles waiting laboratory confirmation.

The latest WMAP release has confirmed many of its predictions to high precision, yet it has left an open question about the 'Axis of Evil'. Finally in the solar system there is the question of the Pioneer anomaly, and also a few rare studies that claim some kind of orbital, or G, evolution on the time scale of Hubble time.


Just questions that might lead nowhere, or, just possibly, be the window into new physics.

Garth
 
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  • #4
marcus said:
If you want, I will sift thru Ellis essay and quote a few things he says.
If that is to your purpose.
...

Wolram, George Ellis has coauthored a book with Stephen Hawking and he is a respected figure in cosmology. Maybe a bit on the old side but not retired. A few years younger than Hawking.

Here is a sample of the kind of thing he says in that article, look on page 25:
=====quote====
4.2.3 Determining the RW parameters Given that a RW geometry is a good description of the observable universe on a large scale, the further issue is what are the best-fit parameters that characterize it, selecting the specific universe we observe from the family of all FL models (Sec.2.1). Important observational issues are:

• Determining the Hubble parameter H0, which sets the overall scale of the observed universe region.

• Determining the trio of the density parameter Omega_0, deceleration parameter q_0, and cosmological constant Lambda (or equivalently the density parameter Omega_Lambda), which are the major defining characteristics of a specific Friedman-Lemaitre model. The CBR data, supernova observations, deep number counts, source covariance functions, velocity measurements, and gravitational lensing observations can determine these quantities.

• Determining the sign of the curvature k, showing whether the universe has closed spatial sections and also whether it is possible for it to recollapse in the future or not. Analyses of the observations should always attempt to determine this sign, and not assume that k = 0 (as is often done).

• Various parameters are used to characterize the nature of dark matter (Sec.2.3.6) and dark energy (Sec.2.3.5). As their dynamics is unknown, these too have to be determined observationally.
=====endquote=====

So, for instance, he is critical of his fellow cosmologists, at least of the run-of-the-mill university cosmologist, because they often simply ASSUME that k = 0 exactly. That is, they favor the EXACTLY FLAT case so much that they oftentimes just take it for granted, according to Ellis.

I have found this to be the case, but I expect the mentality of the ordinary professional cosmologist is probably going to change gradually, partly because of gentle criticism like this from Ellis and partly because of better data.

Ellis says that instead of taking the Omega exactly = 1 case for granted, that it is the cosmologist job to FIND OUT the sign of k, that is, whether Omega is less or equal or greater than 1.

A related question is whether the spatial slices come around and close on themselves---which would make the universe FINITE. Ellis, a mainstream cosmologist who is able to take a critical look at his own profession, says that it is a cosmologist job to measure and FIND OUT if the universe is finite (one way is by measuring curvature) and not just take for granted because you favor this or that.

The astronomy building is just a stone's throw from here. I used to spend time in their coffee room some. I will have to drop in on some grad students before long and see what they are saying. I will let you know when i do.

If you read Ellis you can find more criticisms of the state of the profession. they are mild and it is a lot of work to read his long essay. I will sift through some more if you want. or if this is not what you want let me know
 
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  • #5
wolram said:
What are the (basic) problems with main stream theories of cosmology ?

To me, what's really amazing about the current state of cosmology is that there are so few observational puzzles, and yet still so many theoretical ones. Most of the "discrepant" measurements that I can think of come from extremely questionable methods (like the Pioneer anomaly) or are based on extremely questionable reasoning (like the "axis of evil").

Yet we have such a poor understanding of much of the theory involved. We seem to have a cosmological constant, but have no idea where it came from (the fine-tuning and coincidence problems). We have cold dark matter, but don't know what it is. We have inflation, but struggle to identify the cause.

How did the field get like this? Simple, we don't have enough measurements. We don't understand the dark energy because we've only measured its properties very crudely. Ditto with inflation. Our missions are getting cut like you wouldn't believe. We've entered the era of precision cosmology with a satellite that cost only 150 million dollars.

So, to answer your question, the problem with mainstream cosmology is that it's poorly constrained. [itex]\Lambda CDM[/itex], for all its success, is only a crude parameterization of the real universe and it will be forced to remain that way until we start getting more data to test our theories. Cranks look elsewhere, we don't need new theories, we need new data. :tongue2:
 
  • #6
Wolram, I am trying to sympathize with the alternative views, but, it's difficult. 20 years ago, after a few beers, I would have challenged you to an ass-kicking contest in the parking lot! I was a rebel, back then. I wanted to 'reinvent' the world in my own image. Unfortunately, I did not die a good death. In fact, I did not die at all. My friends were shocked and dismayed by this unlikely turn of events.
 
  • #7
wolram said:
What are the (basic) problems with main stream theories of cosmology ?
...

...
[several different answers]
...
Chronos said:
Wolram, I am trying to sympathize with the alternative views, but, it's difficult. 20 years ago, after a few beers, I would have challenged you to an ass-kicking contest in the parking lot! I was a rebel, back then. I wanted to 'reinvent' the world in my own image. Unfortunately, I did not die a good death. In fact, I did not die at all. My friends were shocked and dismayed by this unlikely turn of events.

This is an odd thread. Everybody seems to have a different idea of what Wolram is asking about, and how to answer.

I now think that I did not understand the original question, and gave an inappropriate response. I will try again.

I now think W. is asking a very simple question. WHAT IS WRONG WITH the standard consensus "Lambda CDM" model?

Every human construct has its weak points---the little imperfections/incompletenesses where it is most easily challenged.

And we should all have these at our fingertips----anyone who knows a theory and works with it should be able to tell you its weaknesses or where it is least good. Even an attentive WATCHER should be aware of the achilles heels of the going theory.

I think Wolram is asking us to tell these. He is not asking us to DEFEND the consensus model. He is not asking us to render a balanced overall judgement and weigh successes against failures and say how-surprisingly-good-all-things-considered type of things.

Since maybe I didnt understand the question the first time, I will try again to answer.

Remember guys, we are NOT ATTACKING the standard LambdaCDM model, we are identifying its most vulnerable least satisfactory points.
When I say something, you do not immediately have to DEFEND the beloved model against me. I am not saying it is wrong I am just trying to point to a "least satisfactory" aspect.

what I hope is that if I can come up with one proposal for a "least satisfactory" part of the model then someone else can suggest some other----and in the end Wolram will have a list of weaknesses of Lambda CDM.

====================

my candidate for the lamest thing about LCDM is the ROTATION CURVE FIT

the Bekenstein TeVeS Mond model fits the rotation curves much better than dark matter does.

I will get a reference link for that. We should probably give Wolram references for the achilles-heels that we offer him.

Please note that I am not ADVOCATING Bekenstein modified gravity. I just use it to illustrate that LCDM could do better in the rotation curves department

=======================

Oh, another lame thing about LCDM might be that nobody has a clue what DM is or where Lambda the "cosmological constant" comes from. And yet those are like 75% and 20% of the whole shebang. In other words it could be said there is a kind of preposterous look and feel to the conventional model. But since that is kind of vague criticism, I will make my nomination for lame thing be the comparatively poor fit of rotation curves.

Now I see that Garth mentioned some of these things already, and other stuff too like CMB "Axis". Why should something as grand as the Background line up with local things like galaxy and solar system? And he mentioned the Pioneer anomaly. Relevant response point for Garth :-) Maybe we should have a poll! what do you think is the weakest aspect of the consensus LCDM model?
 
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  • #8
by Marcus, Remember guys, we are NOT ATTACKING the standard LambdaCDM model, we are identifying its most vulnerable least satisfactory points.
When I say something, you do not immediately have to DEFEND the beloved model against me. I am not saying it is wrong I am just trying to point to a "least satisfactory" aspect.

This is what i mean Marcus, i would hate this thread to become a free for all
debate on why people think the SM is wrong, i only want to know what you
guys think are the (problem areas of the SM) with respect alternate theories
and side issues do not belong here.
 
  • #9
There is of course the small point of the problem of developing a quantum gravity theory.

Apart from indicating that their integration will probably require both QM and GR to be revised in the future, the whole Big Bang would obviously have been a quantum gravity event, so this would seem to be quite a weak point!

Garth
 
  • #10
Garth said:
There is of course the small point of the problem of developing a quantum gravity theory.

Apart from indicating that their integration will probably require both QM and GR to be revised in the future, the whole Big Bang would obviously have been a quantum gravity event, so this would seem to be quite a weak point!

I agree that this is an important puzzle, though it's worth noting that the the "Big Bang" theory, in some theories of inflation, doesn't require a singularity.
 
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  • #11
I am a new member with no experience in physics. I do have a question.

before the big bang, the singularity was like a black hole, I think. If light cannot escape a black hole and nothing can exceed the speed of light, how could there be enough energy for the big bang? Can a black hole explode?
 
  • #12
riley mcmillan said:
I am a new member with no experience in physics. I do have a question.

before the big bang, the singularity was like a black hole, I think. If light cannot escape a black hole and nothing can exceed the speed of light, how could there be enough energy for the big bang? Can a black hole explode?

Welcome Riley,

I see you are a retired welder, so you probably have mature patience and are used to the idea that scientific research rarely supplies certainty.
I think you ask very good questions. In certain sense, which I won't try to explain right now, it is thought that a black hole can indeed explode. In more than one way. Also in a sense the quantum picture of the pit of a black hole DOES resemble the picture at least one school of quantum cosmology has of the big bang. But those are big leaps to take without preparation and clarification.

Keep in mind that the only type of models that have a chance of working at the (bigbang or black hole) singularities are the fuzzy wavy pictures---the quantum models. The clearcut classical ones break down---they simply do not compute at a certain point. But that is OK because various quantum approaches are being worked out and in at least one case may be testable against observations.

The fuzzy models remove the singularities and replace them with a "quantum regime" of very high (but not infinite) density pressure temperature. Your questions are pushing into the area of quantum cosmology.

One thing you could do is look at this scientific (not popular) article
http://arxiv.org/abs/astro-ph/0511557
The guy, Martin Bojowald, is a recognized expert in quantum cosmology of one particular school (loop quantum cosmology).
This is his most recent SHORT overview paper for interested non-specialists (physicists like him, but not in the same specialty) It is 16 pages with relatively few equations. He also has a encyclopedia-like Living Reviews article of 100-some pages and many equations that is even more recent (2006) and a chapter in recent book by World Scentific press. But that is all too hard to read. What I told you is the easy one, of his recent writings.

Another thing you could do is start a thread with your questions. You are always welcome to do this at PF, except when your questions are noticeably similar to what someone else has already asked when they started their thread. I would say yours are different enough but someone else may remember a thread we already have about this.
 
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  • #13
marcus said:
...

my candidate for the lamest thing about LCDM is the ROTATION CURVE FIT

the Bekenstein TeVeS Mond model fits the rotation curves much better than dark matter does.

I will get a reference link for that.

the most recent TeVeS Mond paper I know of is this
http://arxiv.org/abs/astro-ph/0602266
MOND habitats within the solar system
Jacob Bekenstein, Joao Magueijo
"MOdified Newtonian Dynamics (MOND) is an interesting alternative to dark matter in extragalactic systems. We here examine the possibility that mild or even strong MOND behavior may become evident well inside the solar system, in particular near saddle points of the total gravitational potential. Whereas in Newtonian theory tidal stresses are finite at saddle points, they are expected to diverge in MOND, and to remain distinctly large inside a sizeable oblate ellipsoid around the saddle point. We work out the MOND effects using the nonrelativistic limit of the TeVeS theory, both in the perturbative nearly Newtonian regime and in the deep MOND regime. While strong MOND behavior would be a spectacular "backyard'' vindication of the theory, pinpointing the MOND-bubbles in the setting of the realistic solar system may be difficult. Space missions, such as the LISA Pathfinder, equipped with sensitive accelerometers, may be able to explore the larger perturbative region."

This should have references to previous papers that show how Mond can fit galaxy rotation curves better.

Bekenstein was who discovered about Black Hole temperature and entropy and gets credit along with Stephen Hawking. The "BH-entropy formula" should probably be called the "Bekenstein-Hawking entropy formula". He is a famous reputable guy, but he is creative. So he has this TeVeS ("TEnsor VEctor Scalar") modification of gravity that fits rotation curves noticeably better.

In my mind the fact that another model can do better stamps a question mark on the idea of Dark Matter. It doesn't disprove it. DM is still sort of OK but it ruffles darmatter's complacency a little.
 
  • #14
SpaceTiger said:
Most of the "discrepant" measurements that I can think of come from extremely questionable methods (like the Pioneer anomaly) or are based on extremely questionable reasoning (like the "axis of evil").
........
we don't need new theories, we need new data.
Perhaps the new data will bring new theories...:wink:

The Pioneer Anomaly is certainly not built on questionable methods. Turyshev et al. The Study of the Pioneer Anomaly:New Data and Objectives for New Investigation
By now several studies of the Pioneer Doppler navigational data have demonstrated that the anomaly is unambiguously present for both Pioneer 10 and 11. These studies were performed with four independent (and different!) navigational computer programs (Anderson et al., 1998, 2002a; Markwardt, 2002a; Olsen, 2005).
and whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate. Land and Magueijo The axis of evil
The multipoles’ alignment, however, is indeed anomalous, and extends up to ℓ = 5 rejecting statistical isotropy with a probability in excess of 99.9%. There is also an uncanny correlation of azimuthal phases between ℓ = 3 and ℓ = 5. We are unable to blame these effects on foreground contamination or large-scale systematic errors.

Furthermore, as I have posted elsewhere and above, despite the apparent support for the [itex]\Lambda CDM[/itex] model from the acoustic peaks of the CMB power spectrum and the SNIa Hubble diagram, the standard cosmological model continues to face several fundamental problems:-

1. The model continues to depend wholly on two pieces of undiscovered physics, namely dark energy and cold dark matter.

2. The implied dark energy density is so small that it is unstable to quantum correction and its size is fine-tuned to the almost impossible level of one part in ~ 10102.

3. It is difficult to explain the coincidence between the dark energy, dark matter and baryon densities at the present day.

4. Any model with a positive [itex]\Lambda[/itex] also creates fundamental difficulties for superstring theories of quantum gravity.

A number of astrophysical observations have proved difficult to 'shoehorn' into the [itex]\Lambda CDM[/itex] model:-

1. The mass profiles of low surface brightness galaxies appear to be less sharply peaked than predicted by CDM models. (Moore et al. http://www.blackwell-synergy.com/links/doi/10.1046/j.1365-8711.1999.03039.x)

2. The large numbers of sub-haloes predicted in galaxy haloes may make spiral disks subject to tidal disruption on timescales of less than a Giga year. (Moore et al. http://www.journals.uchicago.edu/cgi-bin/resolve?id=doi:10.1086/312287 [Broken])

3. The observed galaxy luminosity function is much flatter than the mass distribution predicted by CDM; attempts to suppress star-formation by invoking significant feedback in low-mass haloes appear to create further problems at higher masses. (Benson et al. http://www.journals.uchicago.edu/cgi-bin/resolve?id=doi:10.1086/379160&erFrom=-7758942045363130217Guest [Broken])

Just a few thoughts to chew over.

Garth
 
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  • #15
I find myself in general agreement.
(Having seen some, but not all, of the papers you cite. And numerous others supporting your main points.)

Cant vouch for your last 3 minor points of technical astrophysics, not having read the supporting papers you give.

this seems like a thorough carefully thought answer, Garth. I wonder if Wolram will be content with it:smile:
He has considerable ability to be dissatisfied with answers.
A bottomless pit of doubt, like any good critic.
 
  • #16
Garth said:
The Pioneer Anomaly is certainly not built on questionable methods. Turyshev et al. The Study of the Pioneer Anomaly:New Data and Objectives for New Investigation


Some further reading:

http://arxiv.org/abs/gr-qc/0601055
Iorio said:
In this paper we investigate the effects that an anomalous acceleration as that experienced by the Pioneer spacecraft after they passed the 20 AU threshold would induce on the orbital motions of the Solar System planets placed at heliocentric distances of 20 AU or larger as Uranus, Neptune and Pluto. It turns out that such an acceleration, with a magnitude of about 8 X 10^-10 m s^-2, would affect their orbits with secular and short-period signals large enough to be detected with the present-day level of accuracy in orbit determination. The absence of such anomalous signatures in the latest data analyses rules out the possibility that in the region 20-40 AU of the Solar System an anomalous force field inducing a constant and radial acceleration of that size is present.

http://arxiv.org/abs/gr-qc/0602089
Tangen said:
If the Pioneer anomaly has a gravitational origin, it would, according to the equivalence principle, distort the motions of the planets in the Solar System. Since no anomalous motion of the planets have been detected, it is generally believed that the Pioneer anomaly can not originate from a gravitational source in the Solar System. However, this conclusion becomes less obvious when considering models that either imply modifications to gravity at long range or gravitational sources localized to the outer Solar System, given the uncertainty in the orbital parameters of the outer planets. Following the general assumption that the Pioneer spacecraft s move geodesically in a spherically symmetric spacetime metric, we derive the metric disturbance that is needed in order to account for the Pioneer anomaly. We then analyze the residual effects on the astronomical observables of the outer planets that would arise from this metric disturbance, given an arbitrary metric theory of gravity. The computed residuals are much larger than the observed residuals, and we are lead to the conclusion that the Pioneer anomaly can not originate from a metric disturbance and therefore that the motion of the Pioneer spacecraft s must be non-geodesic. Since our results are model independent, they can be applied to rule out any model of the Pioneer anomaly that implies that the Pioneer spacecraft s move geodesically in a perturbed spacetime metric, regardless of the origin of this metric disturbance.

http://arxiv.org/abs/gr-qc/0603016
Toth said:
...In this paper we report on our efforts to recover and utilize the complete
set of radio Doppler and telemetry records of the Pioneer 10/11 spacecraft ...
 
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  • #17
marcus said:
I find myself in general agreement.
(Having seen some, but not all, of the papers you cite. And numerous others supporting your main points.)

Cant vouch for your last 3 minor points of technical astrophysics, not having read the supporting papers you give.

this seems like a thorough carefully thought answer, Garth. I wonder if Wolram will be content with it:smile:
He has considerable ability to be dissatisfied with answers.
A bottomless pit of doubt, like any good critic.

Marcus, i am a mechanic, people throw problems at me to solve, some times that means going back to basics.
I can and do sympathise with ST, the lack of data is annoying to say the
least.
It seems to me,(a not very clever person) that a quantum theory of gravity that includes matter, is the first rung on the ladder.
Getting rid of or explaining DE,DM, is the second.
GPB, may have some good news, or bad for GR, i just hope the data it
gives is not inconclusive, but what comes after GPB?
Theories,that can be tested are all well and good, but if the means is not
there to test them they will have to stay on shelf gathering dust.
Forgive me if i am wrong, but trying to fit observations to theories can
only be secondary to meassurments.
 
  • #18
EL said:
Thank you El, certainly there is much ongoing research and discussion needed. My main point was to counter the accusation that the PA was caused by some kind of incompetence or "questionable methods".

It is interesting from your last link paper, (which also contains my quote from the earlier Turyshev et al. paper confirming an unexplained PA) that more data is available and only now being analysed, some narrowly missed being destroyed!
All transmissions of the Pioneer 10/11 spacecraft , including all engineering telemetry, were archived [8] in the form of files containing Master Data Records (MDRs.) Originally, MDRs were scheduled for limited retention. Fortunately, the Pioneers’ mission records avoided this fate: with the exception of a few gaps in the data (mainly due to deteriorating media) the entire mission record has been saved and is available for study.
(Emphasis mine)

What do they hope to achieve from this rescued data?
Therefore, we expect that our analysis of the early data, from a period of time when the spacecraft were much closer to the Earth and the Sun, may help us to unambiguously determine whether the direction of the acceleration is
• sunward-pointing, indicating a force originating from the Sun;
• Earth-pointing that would be due to an anomaly in the frequency standards;
• Along the direction of the velocity vector, indicating an inertial or drag force; or
• Along the spin axis direction that would indicate an on-board systematic force.
It should be pointed out that there are some obstacles along the way towards this goal. A difficult problem [3, 14, 15] in deep space navigation is precise 3-dimensional orbit determination. The line-of-sight component of a velocity is much more easily determined than motion in the orthogonal directions. Unfortunately there is no range observable for the Pioneer spacecraft , which complicates the analysis.
Furthermore, earlier parts of the trajectory were dominated by solar radiation pressure and frequent attitude control maneuvers, which significantly affect the accuracy of orbit determination. Nevertheless, there is hope that these difficulties can be overcome and the analysis will yield the true direction of the anomaly.

Note that in your earlier link papers the problem is reconciling any gravitational effect with the orbits of the other planets, they therefore tend to deny the PA assuming we know all about solar system orbits. However all is not so clear, even in the near solar system! Secular increase of astronomical unit from analysis of the major planet motions, and its interpretation
[itex]\frac{dAU}{dt} = 15 +/- 4[/itex] m/cy Excluding other explanations that seem exotic (such as secular decrease of the gravitational constant) at present there is no satisfactory explanation of the detected secular increase of AU, at least in the frame of the considered uniform models of the Universe.

Also G may be varying: http://articles.adsabs.harvard.edu/cgi-bin/nph-iarticle_query?1986IAUS..114..315K&data_type=PDF_HIGH&type=PRINTER&filetype=.pdf [Broken]

In any case the observation should drive the theory, not the other way round!

Why should there be this discrepency between PA & orbital theory? Perhaps as the PA is of the order of CH it is cosmological in origin and there is a discrepency between the applicability of the Schwarzschild and Cosmological solutions of GR?

BTW wolram, marcus was complementing you. :smile:

Garth
 
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  • #19
Garth said:
The Pioneer Anomaly is certainly not built on questionable methods. Turyshev et al. The Study of the Pioneer Anomaly:New Data and Objectives for New Investigation

I beg to differ. "Measuring" something from an instrument not designed to make that measurement is always questionable...and I think EL's papers covered the theoretical concerns pretty well.


and whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate. Land and Magueijo The axis of evil

Did you even read the WMAP paper or the argument I had with you in the associated thread?


1. The model continues to depend wholly on two pieces of undiscovered physics, namely dark energy and cold dark matter.

Agreed, but it's not a problem with matching the data, it's a problem of not having enough of it.


2. The implied dark energy density is so small that it is unstable to quantum correction and its size is fine-tuned to the almost impossible level of one part in ~ 10102.

3. It is difficult to explain the coincidence between the dark energy, dark matter and baryon densities at the present day.

I referred to these, the "fine-tuning" and "cosmic coincidence" problems already.

The rest of your references refer to the "cuspy cores" problem, "small-scale structure" problem, and something that we understand too poorly to really be called a problem. The first two are genuine concerns with [itex]\Lambda CDM[/itex] and have been discussed at length in other threads.

If the first isn't just an issue of numerical resolution (which is looking increasingly likely), then it's an issue of our lack of knowledge about the dark matter, which falls back into what I was saying about needing more measurements of dark matter properties. The second is, again, a possible issue with the simulations and may have nothing to do with fundamental theory. The third is another example of how we're data-starved. We don't have nearly enough high-z data to understand how the feedback process works.

They are fair concerns, however. I wouldn't yet call them "weak points" with the model because it's still not clear to me that they're not problems with the simulations, but it's still worth keeping in mind.

As for MOND, it comes as absolutely no surprise to me that a theory designed to fit rotation curves can do so with fewer parameters than the standard model. It also came as no surprise to me that relativistic MOND was completely inconsistent with the CMB.
 
  • #20
SpaceTiger said:
Garth said:
and whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate. Land and Magueijo The axis of evil
Did you even read the WMAP paper or the argument I had with you in the associated thread?
Yes - that was the current debate! And I am not the only one who is willing to go with increasing the chance of a false negative. Not everybody agrees with you ST - that is what makes it interesting.
As for MOND, it comes as absolutely no surprise to me that a theory designed to fit rotation curves can do so with fewer parameters than the standard model. It also came as no surprise to me that relativistic MOND was completely inconsistent with the CMB.
Agreed, but it will be interesting to see how Bekenstein responds.

Garth
 
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  • #21
By Garth,
BTW wolram, marcus was complementing you.

Marcus, sorry if my post seemed gruff, it was not meant to be :smile:
 
  • #22
Garth said:
Yes - that was the current debate! And I am not the only one who is willing to go with increasing the chance of a false negative. Not everybody agrees with you ST - that is what makes it interesting.

:confused:

What you said:

and whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate.

You said there was no debate. I'm saying there most certainly is!
 
  • #23
SpaceTiger said:
What you said:
Garth said:
and whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate.

You said there was no debate. I'm saying there most certainly is!
ST I think you are reading me wrong, on this we most certainly do agree!
Perhaps if I had emphasised?:
whether the reasoning behind the Axis of Evil is questionable or not is a matter of current debate

BTW in today's Times newspaper Hidden CJD is new threat to thousands Having eaten British beef during the 1980's I live in dread of suddenly finding my mind going...

The curse of the fear of the false positive - ("Our meat is unsafe" - when it was safe) - you are left with the consequences of the false negative. ("Our meat is safe - when it was not)

Garth
 
  • #24
Garth said:
Perhaps if I had emphasised?:

Oy. I need to renew my eyeglass prescription.
 
  • #25
By Marcus.


So, for instance, he is critical of his fellow cosmologists, at least of the run-of-the-mill university cosmologist, because they often simply ASSUME that k = 0 exactly. That is, they favor the EXACTLY FLAT case so much that they oftentimes just take it for granted, according to Ellis.

Thanks for your help so far Marcus. At the moment i can not see an alternative to making some assumptions, if cosmologists have no data
to work with, what else can they do.
I would like a laymans review of the search for matter in QG theories, from
what i have read string theories are all most out of the picture for now, i
may have the wrong take on that, is there anything new ?

Thankyou, Garth, Space Tiger, Can you shed any light on the (particle)
supersymetry, higs, side of cosmology?
 
  • #26
marcus said:
• Determining the sign of the curvature k, showing whether the universe has closed spatial sections and also whether it is possible for it to recollapse in the future or not. Analyses of the observations should always attempt to determine this sign, and not assume that k = 0 (as is often done).

Just to clarify this point a bit, the assumption of a flat universe (in CMB fits) is made to simplify the analysis. The data are fit with Markov Chain Monte Carlo simulations and the more free parameters there are, the longer it takes to cover the space. You'll see that in the third release, the WMAP team fixes the curvature to flatness for many of their simulations for exactly this reason. They do, however, run a few separate fits that allow the curvature to vary and this is the section you've been referring to in other posts. In other analyses, you'll see the assumption made simply because the flatness has already been measured (in the CMB) to more precision than they could reach.
 
  • #27
wolram said:
Thankyou, Garth, Space Tiger, Can you shed any light on the (particle)
supersymetry, higs, side of cosmology?

The LHC (Large Hadron Collider) is expected to find the Higgs. It also has some chance of detecting a signature (energy deficit) indicative of the dark matter particle. According to Michael Peskin, this won't be enough, and we'll need the ILC (International Linear Collider) to measure the dark matter particle properties. These are all maybes and will depend on which (if any) of the theories of supersymmetry is correct.

However, I don't think a detection or non-detection of the Higgs boson will have much of an impact on cosmology. Inflation is more of a phenomonological model at this point and doesn't rely on the existence of a particular particle species.
 
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  • #28
(Edit crossed with ST's post)
Big Bang studies has been a forced marriage between two incompatible partners: GR and QM, nevertheless the marriage has been, or has the potential of being, very fruitful.

On the one hand GR cosmology has required Inflation, DM and DE, on the other fundamental particle physics has required higher and higher energy accelerators to test the Standard Theory, and you cannot get any higher energy than the BB itself!

The Standard Theory has thrown up countless hypothetical particles that need experimental verification, if they cannot be found in a large accelerator, such as the LHC being built at present, then an alternative is to try to find them in the BB.

Cosmological constraints have filtered out possible candidates, although there are many still to go.

QM requires the Higgs Boson to impart inertial mass to particles and GR requires the energy of its scalar field, or of another hypothetical inflaton particle, to impart a massive exponential expansion in the first 10-35sec or so of the universe's history. It was predicted to be detectable in present particle accelerators but so far without success, perhaps the LHC will deliver.

DM requires a particle with all the right properties to explain the large scale features of the universe including the rotation rates of spiral galaxies. One likely candidate at the moment is the LSP or lightest supersymmetric particle.

We will only know what we are talking about when these particles have actually been discovered, their properties measured and been found concordant with the cosmological constraints.

Until then GR and the Standard Model must remain, well, provisional.

Garth
 
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  • #29
ST, this may be a stupid question, but what evidence do we have that the
CMB is only observed as it is from our view, could observation from another galaxy give different results ?
 
  • #30
wolram said:
ST, this may be a stupid question, but what evidence do we have that the
CMB is only observed as it is from our view, could observation from another galaxy give different results ?
ST will certainly answer this, but if I may butt in, the answer to your question depends on what the CMB actually is. It is most certainly (IMHO) the radation emitted by the surface of last scattering (SLS) when the universe emerging from the Big Bang cooled enough for atomic hydrogen to form and the universe become transparent.

As such it would look more or less the same from any galaxy at this present epoch. Its temperature will depend on the epoch of observation.

However the largest anisotropy of the CMB, 100X larger than the rest, is the dipole caused by our peculiar motion relative to that SLS. As each galaxy has its own peculiar motion, and planets their own trajectories within those galaxies it will be this dipole that will differ from planet to planet, star to star and galaxy to galaxy.

Garth
 
  • #31
wolram said:
ST, this may be a stupid question, but what evidence do we have that the
CMB is only observed as it is from our view, could observation from another galaxy give different results ?

If inflation is correct, then the CMB should look different from other locations, but have the same statistical properties. Sometimes, we can remotely infer the properties of the CMB by looking at gas that is coupled to it. Here's one such example:

http://adsabs.harvard.edu/cgi-bin/n...pe=HTML&format=&high=4428679b1d05070"

It's not a very powerful technique, however, and can only give us very crude measurements of the temperature. Measuring the anisotropies remotely is probably a long way off, if possible at all.
 
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  • #32
A question i have with held for lack of research, but, how can it be shown that the CMB is a relic of the BB, every one seems to assume it is, but i guess, there is not a unique signature for this radiation.
 
  • #33
There have been sugestions from the Steady State 'school' in the 1970s that the CMB might be either the sum total of background galaxies - Olber's paradox red-shifted into the micro-wave region.

Or, in Fred Hoyle's mass field theory fundamental particle masses decrease as you out in space until you reach the membrane where m = 0, which we interpret as the BB. The CMB was then claimed to be the smoothed out radiation from galaxies beyond that membrane, (presumeably with negaitve masses.)

These suggestions were long shots, which did not explain the CMB isotropy and would not have survived the discovery of the anisotropies at the 10-5 level.

Garth
 
  • #34
Thankyou , Garth, i admit i am learning a lot about the fundamental reasons
for the SM, but i am cursed with the ability to see other views, i think it is
like a retail outlook, one sees an opening and tries to fill it, but this is wrong
for cosmology, one should not try to fill in the gaps until the market ressearch
has been done.
 
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1. What is cosmology?

Cosmology is the scientific study of the origin, evolution, and structure of the universe. It seeks to understand the fundamental laws and principles that govern the universe, as well as the various objects and phenomena within it.

2. What are some of the main theories in cosmology?

Some of the main theories in cosmology include the Big Bang theory, which proposes that the universe began as a singularity and has been expanding ever since, and the inflation theory, which suggests that the universe underwent a rapid period of expansion in its early stages.

3. What are some of the biggest problems in cosmology?

One of the biggest problems in cosmology is the mystery of dark matter and dark energy, which make up the majority of the universe's mass and energy but cannot be directly observed. Other problems include the flatness problem, horizon problem, and the lack of a unified theory that can explain all of the fundamental forces in the universe.

4. How do scientists study cosmology?

Scientists study cosmology through a combination of observations, mathematical models, and experiments. They use telescopes and other instruments to observe the universe, and then use mathematical equations and computer simulations to test and refine their theories.

5. What are some practical applications of cosmology?

Cosmology has many practical applications, including helping us understand the origins of the universe and our place within it. It also has implications for technology, such as in the development of advanced telescopes and space exploration. Additionally, studying cosmology can lead to advancements in fields such as physics, astronomy, and mathematics.

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