I would agree that our "estimation" of "baryonic matter" (does an electron/positron "count" as a "baryon" in this "method" by the way?) does not jive with the mass requirement suggested by galaxy rotation patterns (assuming no flow of current through the galaxy).
I was referring really to nucleosynthesis constraints, so in the strictest (and proper) sense an electron is not a baryon, it is a lepton.
I fail however to see how our technology could possibly allow us to account for "all" the "normal matter" in a distant galaxy. We can't seem to accurately measure the black hole that sits at the core of a galaxy, so how can we be sure how much mass is actually missing to allow us to explain those rotation patterns? If the dust of the universe blocks more light than we expect, wouldn't we first want to factor in these changes *before* deciding how much "missing mass" there really is?
There could be a shipping container full of unknown objects sitting on a weighbridge. The weighbridge could give you a very good estimate of the total mass involved in the shipping container. If you knew the container was full of footballs, and you knew the average mass of a football, and you could work out how many could be squashed in the container, and if the total mass of the footballs and the container itself only came to 5% of what the weighbridge said the weight was, then you could have to give your head a serious scratch.
You don't need to know the exact mass of the clump of footballs in the centre to work out how much mass in footballs there is overall.
Ok ok ok.. terrible analogy I know, but I was struggling to understand your point here MM.. truly.
Well, let's play the "if" game for a second. If there are "dusty threaded regions" between us and a given galaxy, it could cause us to underestimate the amount of light coming from a galaxy. It could have a more significant effect on distant galaxies than it has on closer ones, but due to the threaded nature of the galaxy, it could have more of an effect on some galaxies than on others. A "typical correction" make grossly underestimate the amount of light that is actually being blocked, and thereby make us grossly underestimate the number of visible light sources and normal baryonic material in any given galaxy.
Forgive me if you have already answered this, but these dusty threaded regions, are they distributed evenly? Could we not infer their presence statistically? I.e. would we not have already discovered this after 40 odd years of looking at dust and gas in space to see how it affects light from stars and galaxies and notice this "unusual" effect you put forward?
How can you be so certain that a "typical correction" is anything more than "gross oversimplification" that already grossly underestimates the amount of light emitted by various galaxies.
Because I have seen and dealt with the research and statistics and it would be doing a generation of scientists and theorists and experimenters a great disservice to call it a "gross oversimplification".
In that sense most of what we do in cosmology or astrophysics would be a gross oversimplification but I think to a laymen that would imply it is next to useless and pretty much something somebody just guessed as they got out of bed one morning... i.e. I don't quite think it is fair.
It seems to me that in light of recent "discoveries", it would be "prudent" to go back to the drawing board. Even deciding what to do with that information has a "subjective" component to it as Tubbythin pointed out to me earlier. We can "subjectively' decide to simply increase the size and light output of the existing point sources *or* we can subjectively increase the number of point sources. Given the amount of "missing mass" that we're trying to account for, it seems "prudent" to increase the number of point sources and stuff as much "normal matter" into these equations as we can fit *before* we claim this material is some sort of exotic matter with ad hoc properties galore.
But. We. Have.
I may be completely misunderstanding you but please understand that the last thing on the mind of any cosmologist is to just go round saying "here... we aint got a clue what this is .. it must all be stuff we dont know and cant understand".
The concepts evolved were forced by very tight restrictions on theory and experimental results, not a consequence of being lax and lazy in applying known ideas and theories.
What I think you are suggesting has been pretty much to death over the last 20 odd years with no real hint of success. We are left with these strange ideas because we have pretty much exhausted everything else we can think of (not to say we are not still trying).
But if you accept the constraints on baryonic matter by nucleosynthesis and other bits and bobs then it dont matter how much you messed up on how many stars a galaxy has, or how much dust there is, or how many MACHOs there are, the simple fact is you can add that stuff til the cows come home but you are still not going to match everything else we see... not by a long shot.
Where did you come up with that 20% figure "at most"?
Your link:
http://www.nytimes.com/2008/05/17/science/space/17univ.html?_r=1
The results also mean that there is about 20 percent more mass in stars than previously thought. But since stars make up such a small percentage of the universe to begin with — dark matter and dark energy account for 95 percent or so — it is a small adjustment over all.
At worst case it's still a "missing mass" problem. It still makes little sense to "assume" that missing mass has any unique or "special properties" until and unless otherwise demonstrated empirically.
If a part in a car's engine is not performing as expected, how do you demonstrate its properties until you have identified which part in the car is the one that is "faulty" and compared it to what you would expect to happen in a normal car engine?
You seem to be claiming a mechanic can just look a car engine, identify the part that is wrong without hearing the engine work or looking under the bonnet, and then instantly detail how that part would behave without even touching it or playing with it.
Or am I being unfair?
There are many reasons why galaxies might emit an excess of gamma rays, including shock waves and discharges and other more "likely" sources than "hypothetical" forms of matter with hypothetical properties galore.
Indeed there is. There are many ways of emitting gamma rays.
The trick is to look for the details and not just on whether gamma rays are emitted or not.
I think maybe there is too much concentration on the simple fact that gamma rays are observed or expected. That, alone, tells you next to nothing.
It is all in the details
