Noncommutative geometry naturally includes inflation epoch

In summary: Higgs field to fall back to its normal energy and space to contract.The connection between Guths' inflationary field and the cosmological constant is made explicit in a 1988 paper by Steven Weinberg and Abdus Salam, and again in a 1992 paper by Andrei Linde and Mikhail L. Smirnov.In the context of String theory, the Higgs field may play a similar role to the inflaton in the Standard Model.Yes, that is what they are doing.
  • #1
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In ordinary GR geometry, the Higgs field cannot play the rôle of the inflaton, so to imagine inflation one has to introduce some exotic field that is not part of the Standard Model. Something completely made up must be introduced to make it work.

Not so in the context of non-commutative geometry (NGC) say William Nelson and Mairi Sakellariadou.

==quote==
...within the noncommutative geometry approach to unifying gravity and the standard model, it is possible to have an epoch of inflation sourced by the dynamics of the Higgs field.

In addition, this type of noncommutative inflation could have specific consequences that would discriminate it from alternative models. In particular, since the theory contains all of the standard model fields, along with their couplings to the Higgs field, which in this scenario plays the rôle of the inflaton, a quantitative investigation of reheating should be possible. More significantly, the cosmological evolution equations for inhomogeneous perturbations differs from those of the standard Friedmann-Lemaître-Robertson-Walker cosmology [7]. This raises the possibility that signatures of this noncommutative inflation could be contained within the cosmic microwave background power spectrum.
==endquote==

http://arxiv.org/abs/0903.1520
Natural inflation mechanism in asymptotic noncommutative geometry
William Nelson, Mairi Sakellariadou
3 pages
(Submitted on 9 Mar 2009)
"The possibility of having an inflationary epoch within a noncommutative geometry approach to unifying gravity and the standard model is demonstrated. This inflationary phase occurs without the need to introduce 'ad hoc' additional fields or potentials, rather it is a consequence of a nonminimal coupling between the geometry and the Higgs field."

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

Nelson and Sakellariadou explain why the Higgs field does not work

==quote==
Unfortunately, it has proved difficult to naturally embed inflation within an underlying fundamental theory. Inflation most naturally occurs when the dynamics of the universe are dominated by the evolution of a scalar field, the inflaton, slowly rolling in its potential; the form of the potential defines the type of the inflationary model.

There is only one scalar field within the standard model of particle physics, the Higgs field, and it is naturally hoped that this could play the rôle of the inflaton. However, it has been shown[4] that inorder for the Higgs field to produce the correct amplitude of density perturbations, its mass would have to be some 11 orders of magnitude higher than the one required by particle physics. This conclusion was however reached using general relativistic cosmology and here we re-examine the calculation in the context of cosmological noncommutative geometry[5, 6, 7].
==endquote==

We already have an earlier paper by the same authors about NCG cosmology.
 
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  • #2
Here's the earlier Nelson Sakellariadou paper, that appeared three months ago.

http://arxiv.org/abs/0812.1657
Cosmology and the Noncommutative approach to the Standard Model
William Nelson, Mairi Sakellariadou
4 pages
(Submitted on 9 Dec 2008)
"We study cosmological consequences of the noncommutative approach to the standard model. Neglecting the nonminimal coupling of the Higgs field to the curvature, noncommutative corrections to Einstein's equations are present only for inhomogeneous and anisotropic space-times. Considering the nominimal coupling however, we obtain corrections even for background cosmologies. A link with dilatonic gravity as well as chameleon cosmology are briefly discussed, and potential experimental consequences are mentioned."

A central feature of what WN and MS are doing is that they include a coupling between the Higgs field and the geometry. This is how they get inflation to work in the paper that came out today.

Their work draws on this earlier paper by three Russians, the reference [4] mentioned earlier
http://arXiv.org/abs/0812.4950
Standard Model Higgs boson mass from inflation
Fedor L. Bezrukov, Amaury Magnin, Mikhail Shaposhnikov
5 pages, 3 figures
(Submitted on 29 Dec 2008)
This is where it was found that the Higgs mass would have to be many orders of magnitude greater. (But they also seem to get around this by the same means, introducing a nonminimal coupling of the Higgs to the geometry.)

I haven't figured out how important NCG is to this result, since Bezrukov et al do not use it.
 
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  • #3
I would be curious to see more in-depth work about this, it seems like at the end they conclude their paradigm can produce much more specific calculations and predictions than they produce in just this introductory paper.

Is the nature of what they're doing such that they will be able to produce more specific results once the exact Higgs mass is known?
 
  • #4
In ordinary GR geometry, the Higgs field cannot play the rôle of the inflaton,...

Why is that?
Brian Greene in FABRIC OF THE COSMOS, Chapter 19 Deconstructing the Bang, spends several pages drawing what appear to be direct linkages between Einstein's cosmologcal constant and Guths' inflationary field:

In the 1980's...the cosmological constant resurfaced in a dazzling new form...Guth discovered that a supercooled Higgs field does have an important effect on the expansion of space: like a cosmological constant it exerts a repulsive gravitational force that drives space to expand...A Higgs field perched above its zero energy value can provide an outward blast driving space to swell...only for the briefest of instants...
 
  • #5
I checked Roger Penrose THE ROAD TO REALITY, Chapter 28.4 he says

...it will be particularly instructive to exame the particular cosmological model on which this (inflationary) expansion is based...This is the steady state verson of deSitter space...It is necessary to introduce a new scalar field...solely in order to produce an inflationary phase in the early universe...It is sometimes referred to as a Higgs field but it does not seem to be the 'ordinary' one...(and he goes on to discuss) no ordinary matter (has the property required) and the Einstein equation has to be taken in the form where a cosmological constant is included...

Again this seems to imply a linkage...Greene discusses two differences in inflationary vs cosmological fields, I could not figure out what Penrose had in mind...
 
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  • #6
Natural Inflation Mechanism in asymptotic...

This raises the possibility that signatures of this noncommutative inflation
could be contained within the cosmic microwave background power spectrum.

Isn't that just the kind of thing you love to see!

Reading the above paper, not following the math, it seems like the issue is whether a Higgs like (standard model) field coupled to geometry or whether the inflationary Higgs field was considerably different than todays is the better model...Seems like

...the inflationary quantum mechanical phase transition to a vacuum different from the one we are familiar with today
from Roger Penrose could sure have been different than todays...

I have forgotten just how Guth came across his inflationary expansion but it has always seemed like a lucky find, a good overlay, rather than the culmination of a series of natural events...
 
  • #7
Naty1: Do you suppose that when Penrose says "a Higgs field", he is using this as a synonym for "a scalar field"?
 
  • #8
Do you suppose that when Penrose says "a Higgs field", he is using this as a synonym for "a scalar field"?


If you mean does Penrose know Higgs is scalar, I'm sure he does. It's the only scalar field in the standard model so I dout he'd miss it!

If you mean is he using Higgs as a generic term for scalar, my interpretation of his descriptions leads me to say No...

Both Greene and Penrose refer to the phase transition, rolling potential/mexican hat style associated with spontaneous symmetry breaking of the inflationary cycle...so the concepts are the same but maybe their formulations of the field transition are different...

What I should have also mentioned: I like the idea in Nelsons paper even if Higgs could be included in GR...but right now I don't understand those Higgs in/out implications either way...
 
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  • #9
Coin said:
Naty1: Do you suppose that when Penrose says "a Higgs field", he is using this as a synonym for "a scalar field"?

Yes, I think this is the case. One should not rely on popular science, since it makes lots of simplifications: in this case, presumably Penrose doesn't want to have to define a scalar field, so calls them "Higgs-type" fields, but which are not the "ordinary" Higgs.
 

FAQ: Noncommutative geometry naturally includes inflation epoch

What is noncommutative geometry?

Noncommutative geometry is a mathematical framework that studies spaces and their geometry using noncommutative algebra, which is a type of algebra where the order of operations matters. It is a generalization of traditional geometry that provides a new perspective on understanding the structure of space.

What is the role of noncommutative geometry in the inflation epoch?

Noncommutative geometry has been proposed as a framework to study the physics of the early universe, particularly during the inflation epoch. It provides a mathematical language to describe the dynamics of the universe during this period and offers new insights into understanding the origin of the universe.

How is noncommutative geometry related to the inflationary model?

The inflationary model is a cosmological theory that explains the rapid expansion of the universe in its early stages. Noncommutative geometry has been shown to naturally incorporate the principles of this model, making it a powerful tool for studying inflation and its implications.

What are the advantages of using noncommutative geometry in cosmology?

Noncommutative geometry allows for a more comprehensive and unified understanding of the universe by incorporating both space and time into its mathematical framework. It also provides a way to address some of the fundamental questions in cosmology, such as the origin of the universe and the nature of space-time.

What are some current research efforts in applying noncommutative geometry to cosmology?

There are ongoing research efforts to use noncommutative geometry to study various aspects of the universe, such as the cosmic microwave background radiation, dark energy, and the early universe. Scientists are also exploring the potential of this framework in developing a theory of quantum gravity, which could have profound implications for our understanding of the universe.

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