The way I see it is this:
Theory A. Light travels to infinity without losing light
Observation 1. Light redshifts and does not seem to travel to infinity
Theory B. The galaxies are receding, redshifting the light
Theory C. Since theory B puts us at the center of reality, let's make it so space is expanding
Theory D. If space is expanding, in the past it was smaller, and there was a beginning of time
Observation 2. The horizon problem.
Theory E. Everything interacted with everything, then hyper-expanded, then stopped hyper expanding
(skip some steps)
Theory M: Dark energy did it
(skip some steps)
Theory T: In the multiverse, any thing can happen, even different laws of physics (that makes the multiverse of inflation way different than Everettian QM, which operates on the wave equation), and an infinite number of universes are made, and ours happens to do this cool dark energy inflation stuff
Observation 3: BICEP2 found dust.
What I'm questioning Theory A.
Theory A says light travels forever, which was established in the 1800's before we knew there were galaxies other than the Milky Way, before we detected redshift.
We observe a finite amount of light from a finite distances.
That's an empirical fact.
That is to say, the empirical and theoretical range of electromagnetic radiation are not in agreement.
The articles I post cast great doubts over the CMB being what it is claimed to be, the existence of a "young universe", the nucleosynthesis, and the growing skepticism over the scientific value of inflation.
What else does the Big Bang have to rest on?
"Is there a better theory?"
Take Hubble's Law, v = H D where v is the apparent recessional of velocity of a galaxy at distance D, and H is Hubble's Parameter. If the apparent recessional velocity is only apparent, and not actual, we could actually take that term (H D) from the distant galaxy (such that its v = 0) and say put it into the frequency (f) of the photon f = (c - H * D) / w where w is the wavelength from which it was emitted.
In this theory, redshift is a feature of light itself.
I know this lends itself to many criticisms and open questions, however, no one has provided Dark Energy, and supposedly it makes up 68% of the observable universe, which doesn't seem consistent with observation.
Here's something else I found, when looking into it:
"[If the redshifts are a Doppler shift] ... the observations as they stand lead to the anomaly of a closed universe, curiously small and dense, and, it may be added, suspiciously young. On the other hand, if redshifts are not Doppler effects, these anomalies disappear and the region observed appears as a small, homogeneous, but insignificant portion of a universe extended indefinitely both in space and time."
— E. Hubble, Monthly Notices of the Royal Astronomical Society, 97, 506, 1936
I also found that the temperature of space was predicted to be 3K by Aurthor Eddington in 1926. The Big Bang's predictions where nowhere near that, and when the CMB was discovered in the 60's at 3K, the discovery was claimed to be evidence of an expanding universe.
If cosmology is why computers worked or airplanes flew, or was ever corroborated by a lab experiment, then I probably wouldn't be questioning. But it takes places millions of light years away, millions of years ago. And the experts in the articles I cited were calling it into question.
Is there a cognitive bias to have a creation myth?
We observe a finite amount of light from a finite distances.
That's an empirical fact.
That is to say, the empirical and theoretical range of electromagnetic radiation are not in agreement.
Why does observing a finite amount of light from a finite distance contradict anything about the range of electromagnetic radiation?
(Also... has anyone read http://en.wikipedia.org/wiki/Redshift? It's... well... good.)
I am submitting this on behalf of MazeHatter, who originally posted it here in the most recent open tread. Go there to upvote if you like this submission.
Begin MazeHatter:
I grew up thinking that the Big Bang was the beginning of it all. In 2013 and 2014 a good number of observations have thrown some of our basic assumptions about the theory into question. There were anomalies observed in the CMB, previously ignored, now confirmed by Planck:
http://www.esa.int/Our_Activities/Space_Science/Planck/Planck_reveals_an_almost_perfect_Universe
We are also getting a better look at galaxies at greater distances, thinking they would all be young galaxies, and finding they are not:
http://carnegiescience.edu/news/some_galaxies_early_universe_grew_quickly
http://mq.edu.au/newsroom/2014/03/11/granny-galaxies-discovered-in-the-early-universe/
B. D. Simmons et al. Galaxy Zoo: CANDELS Barred Disks and Bar Fractions. Monthly Notices of the Royal Astronomical Society, 2014 DOI: 10.1093/mnras/stu1817
http://www.sciencedaily.com/releases/2014/10/141030101241.htm
http://www.nasa.gov/jpl/spitzer/splash-project-dives-deep-for-galaxies/#.VBxS4o938jg
Although it seems we don't have to look so far away to find evidence that galaxy formation is inconsistent with the Big Bang timeline.
http://www.natureworldnews.com/articles/7528/20140611/galaxy-formation-theories-undermined-dwarf-galaxies.htm
http://arxiv.org/abs/1406.1799
Another observation is that lithium abundances are way too low for the theory in other places, not just here:
http://news.nationalgeographic.com/news/2014/09/140910-space-lithium-m54-star-cluster-science/
It also seems there is larger scale structure continually being discovered larger than the Big Bang is thought to account for:
http://www.sciencedaily.com/releases/2014/11/141119084506.htm
D. Hutsemékers, L. Braibant, V. Pelgrims, D. Sluse. Alignment of quasar polarizations with large-scale structures. Astronomy & Astrophysics, 2014
http://www.sciencedaily.com/releases/2013/01/130111092539.htm
These observations have been made just recently. It seems that in the 1980's, when I was first introduced to the Big Bang as a child, the experts in the field knew then there were problems with it, and devised inflation as a solution. And today, the validity of that solution is being called into question by those same experts:
http://www.physics.princeton.edu/~steinh/0411036.pdf
What are the odds 2015 will be more like 2014 where we (again) found larger and older galaxies at greater distances, or will it be more like 1983?