Earnest Guest said:
Let me try this again. The Bullet Cluster is proof of ΛCDM because 90% of the baryonic mass is in the form of gas, yet the gravitational lensing appears to follow the 10% of the stellar mass. And we are convinced that 90% of the baryonic mass is in the form of gas because... (please insert a reference here that measures the mass of the superheated gas and doesn't assume ΛCDM to produce a model).
OK, let
me try again. Here is the logic:
(1) We assume that we understand elementary particle physics because we can measure protons, electrons, and atoms here on Earth and how much radiation they emit in certain circumstances. If you don't accept this, than we have no basis for a discussion.
(2) We assume that we understand stars, how much light they emit, and how much they weigh. Again, if you don't accept this, same comment as above.
(3) We measure how much X-ray radiation is emitted by the Bullet Cluster. From this we can calculate how much hot gas is present in the cluster, and where it is.
(4) From the brightness of the galaxy, we can calculate how much mass is present in stars.
(5) We measure the deflection of light that occurs by measuring the distortion of light from galaxies behind the Bullet Cluster. This is called gravitational lensing. From this, and the theory of General Relativity, we can calculate how much mass is present in the cluster. The theory of General Relativity has passed every experimental test that has been thrown at it, so we are highly confident it is correct. If you don't accept it, please propose an alternative theory that is at least as successful, quantitatively, at explaining the observations.
These calculations give the following results. About 15% of the total mass of the cluster is in hot gas; about 1-2% of the mass of the cluster is in stars; about 85% of the mass of the cluster is invisible, but we know it is there because it bends the light. This quantity of "dark" matter is very consistent with the amount that we get from measuring the CMB radiation, and from measuring galactic rotation curves, giving us some confidence that we have a model that makes sense.