And add the McGill group to the list, with their "matter bounce" investigations. Googling "matter bounce" gets a bunch of hits, as I recall. The senior person, the ringleader, is Robert Brandenberger . But I'm particularly impressed by Yi-Fu Cai.
Their scenarios are different from string and Horava---also distinct from Loop, but with just enough similarity to permit some crossover.
One reason I like Yi-Fu Cai is that (whereas Ashtekar Loop cosmology has always allowed inflation, never argued that it wasn't needed) Cai (and Brandenberger as well) typically find that when there is a bounce
inflation is not needed. The McGill people seem inclined to
pointedly omit inflation from their scenarios. Here is how the point is made in the Cai&Wilson-Ewing paper I summarized earlier.
http://arxiv.org/abs/1412.2914 (google search "LambdaCDM bounce")
==quote Cai&Wilson-Ewing page 1==
I. INTRODUCTION
Observations of the cosmic microwave background (CMB) —most recently [1, 2]— have clearly established that scalar perturbations in the early universe were nearly scale-invariant. It is thus necessary for any realistic cosmological model to generate, in some fashion, scale-invariant perturbations.
To achieve this, many cosmological models rely on the presence of matter fields (typically scalar fields)
that have not yet been observed in nature. The new matter fields are
necessary in these models as they play an essential role in the generation of scale-invariant perturbations. While it is of course a requirement for any cosmological scenario to predict near scale-invariance in order to be potentially viable, there are some cosmological scenarios where
it is possible to avoid the weakness of postulating the existence of unknown matter fields and nonetheless obtain scale-invariance.
===endquote===
It's a strong opening statement, I think. Here are two postdocs. They are saying that they will DISPENSE WITH INFLATION and still get the good results that serve, in many people's minds, to necessitate and justify assuming inflation. And they explain that they want to dispense with inflation because it requires mythology---assuming the existence of exotic matter fields which have never been seen in nature.
===Cai&Wilson-Ewing page 1, continued===
We shall study one such model in this paper. This cosmological model consists of a spatially flat Friedmann-Lemaître-Robertson-Walker (FLRW) universe, with a positive cosmological constant, cold dark matter, and radiation. These are three ingredients known to be present in our universe, and we will not assume the existence of any other matter fields. We also assume that the initial conditions are such that the space-time curvature is small and the universe is large and contracting.
As the universe contracts, the space-time curvature will increase, and quantum gravity effects are expected to become important at some point, likely when the space- time curvature nears the Planck scale. In this work, we will assume that loop quantum cosmology (LQC) captures the salient non-perturbative quantum gravity effects in the very early universe...predicts that a bounce occurs near the Planck scale and that, once these quantum gravity effects are included, the space-time is free of the singularities that appear in classical general relativity [3–5].
Thus, this model will be that of a bouncing universe, with a matter content of radiation and cold dark matter and a positive cosmological constant. ...if the pressure is slightly negative, for example due to the presence of a positive cosmological constant, then the long wavelength perturbation modes will be almost scale-invariant with a slight red tilt. Therefore, in the model considered here, we expect the modes that become large during the epoch of the universe that is dominated by cold dark matter to be almost scale-invariant, and those that become large when the effective equation of state is slightly negative to have a small red tilt.
In this paper we calculate the spectrum of the cosmological perturbations for this model.
==endquote==
So they are going to do without exotic matter so far never observed and its associated quaintly shaped "plateau" potentials as well, with no particular reason to support them either. :)
They are going to study a contracting ΛCDM universe starting from its matter&Lambda dominated phase, proceeding thru the radiation-dominated era, to the stage where quantum effects become important, and then back out, as it re-expands, thru radiation era to where matter and the cosmological constant again predominate. And they are going to get the good results without inflation.
It's a bold initiative. And they still have more to do (e.g. in ordinary baryonic matter in addition to DM). They discuss future work to be done on this project in the final section of the paper--also worth checking out.
At the moment I think this December 2014 "ΛCDM bounce" paper could be the most consequential one on the Combined 4th quarter MIP poll. Perhaps even the most important to have appeared all year.
https://www.physicsforums.com/threa...mip-poll-for-most-important-qg-papers.789671/
