I'm no expert obviously, but I have noted that LambdaCDM now wins out on all structure scales.
"Figure 2 (right panel) shows how well the DC14 and NFW profiles fare in reproducing the observed Tully-Fisher relation. In the lower Mstar mass ranges, the NFW profile predicts these galaxies to have larger Vlos than observed, while the DC14 density profile adheres closely to the observed Vlos over the whole stellar mass range."
Fig 2 – The left panel shows the velocity function, which is the number distribution of galaxies as a function of line of sight rotational velocity, Vlos. Ignoring the dark purple line which indicates maximum circular velocity for Cold Dark Matter (CDM), the DC14 model in red is contested against the NFW profile in light purple. The right figure relates Vlos with galaxy stellar mass M*, ie the Tully-Fisher relation. The data points are observational results. In both plots, the DC14 model closely tracks observations while the NFW profile deviates far from observations. Figure 2 from paper."
"Figure 3, our last figure of the day, shows exactly this. Despite doing better than the NFW profile, both WDM and SIDM are not able to fit the velocity function and Tully-Fisher relation as well as we expect.
Fig 3 – These are the same plots as Figure 3 with the left figures showing the velocity functions and the right figures showing the Tully-Fisher relations, but comparing warm dark matter (WDM) in blue and self-interacting dark matter (SIDM) in green against the NFW profile in purple. Figure 4 in paper."
[
http://astrobites.org/2015/06/12/the-labor-of-outflows-against-dark-matter-halo/ ]
Assuming WDM and SIDM did roughly as well as other alternative theories that didn't have the initial CDM cusp problem, those are now worse in reproducing observations for spiral galaxies.I'm obviously no expert here either, but I have noted that QM doesn't need to be modified to "accommodate GR". Here is what a theoretical physicist has to say on the matter:
"It’s often said that it is difficult to reconcile quantum mechanics (quantum field theory) and general relativity. That is wrong. We have what is, for many purposes, a perfectly good effective field theory description of quantum gravity. It is governed by a Lagrangian
(1)S=∫d4x−g−−−√(M2plR+c1R2+c2R2μν+c3M2plR3+…+Lmatter)
This is a theory with an infinite number of coupling constants (the c
i and, all-importantly, the couplings in L
matter). Nonetheless, at low energies, i.e., for ε ≡ E
2M
2pl ≪ 1, we have a controllable expansion in powers of ε. To any finite order in that expansion, only a finite number of couplings contribute to the amplitude for some physical process. We have a finite number of experiments to do, to measure the values of those couplings. After that, everything else is a prediction.
In other words, as an effective field theory, gravity is no worse, nor better, than any other of the effective field theories we know and love.
The trouble is that all hell breaks loose for ε ∼ 1."
[
https://golem.ph.utexas.edu/~distler/blog/archives/000639.html ]
If I understand this correctly - and I don't do quantum field theory - it is GR's non-linear nature (seen in black hole systems) that is the problem, not that QM would be inapplicable as is. The latter is a folk physics myth, it seems to me.
Also, I'm not sure what you mean by space being "continuous and real". It is continuous in the sense of a continuous metric, but both GR and QM makes larger systems non-local relative clocks and non-local relative space.
The metric is real valued (I think, but with a complex valued signature, is it not?), compare with how QFT is worse since some stuff naturally comes out complex valued. But if you mean philosophic "real" science won't help - space is part of nature, is all.
