Minnesota Joe said:
I definitely wasn't! It just helps explain some of the controversy to me personally.I apologize, but I still don't follow this. Are you saying that adding c makes the realism assumption? Or the parameters themselves?I'm not saying changing the wording around changes anything, except my the level of confusion!
That is at least the 3rd sense of realism you have listed:
1. EPR-realism
2. Observer independent reality
3. Hidden variables
The don't seem precisely the same thing and I think that is the type of ambiguity I was trying to resolve.
I'm also not doubting your report of the consensus. I would have said the same thing and in fact did say the same thing prior to reading in quantum foundations.
I can't do anything to resolve the ambiguity of the different words and their precise definitions, no one can. What is not ambiguous is what the various papers (EPR, Bell, Aspect, etc) do with the math. Keep in mind that Bell ASSUMED the reader knew EPR intimately. He was writing for a very small audience at the time. So he didn't bother to write for anyone other than those who would understand the main argument when published in 1965.
Everyone concluded after EPR that there was a stalemate between 2 main factions. Einstein (on one side) believed local realism was tenable and a more complete quantum theory was possible. Bohr (leading the other side) didn't. Sadly, both died without learning of Bell. With the stalemate, EPR had proved that for an entangled system (Alice and Bob, or a and b) could have 2 non-commuting observables that could be predicted in advance. EPR said that was enough to conclude that each of the entangled particles had well defined values prior to measurement - something that Quantum Theory does NOT provide. They acknowledged that their conclusion would not be valid if you require that 2 or more of the values be predicted simultaneously - something that is not possible. Of course the other faction seized on that as a good reason not to accept the EPR conclusion. No one saw a way out.
Then Bell came along. He realized that looking at JUST 2 observables wasn't good enough. If EPR was correct, EVERY POSSIBLE observable must be predetermined. I.e. not just 2, as EPR thought they proved, but 3, 4, ... infinite.
So Bell put together an example of 3. It turns out that for almost ANY 3 observables on an entangled system, there are NO values which match the quantum expectation values.
I won't repeat the Bell argument here as that is not the subject of this thread. This thread is simply to assure anyone interested that a) realism is an assumption of Bell; and b) that it is is generally accepted by the scientific community.
So what you are looking for is someplace in Bell in which there are 3 possible observables that are compared to see if they could match the quantum expectation values. Bell used spin components for his observables, after Bohm's example discussing the EPR issue. Bell labels those components a, b and c. You can see them in full view in Bell's (15). Note that you cannot measure all 3 simultaneously. Bell realized that under the EPR argument, that didn't matter! That's because their assumption was explicitly saying it didn't, and everyone had simply accepted that as reasonable. But we now know it was not.
So to recap: when you attempt to imagine a large set of pairs of entangled particles, and then measure the spin components at various angles, you quickly find that if QM averages are correct, then there cannot be objective reality (i.e. independent of the measurement decision of the observer). Again, read the full Bell paper to follow the argument. Except that Bell is probably the worst paper to read to learn this for the reasons I explained. Better is to read Mermin:
Is the moon there when nobody looks? Reality and the quantum theory
or perhaps my web page:
Bell's Theorem With Easy Math
Again, there is no serious controversy over the main point (the math). The primary controversy is arguments over the best words to use to describe the Bell result. Here are the words I think do the best overall job.
No physical theory of local Hidden Variables can ever reproduce all of the predictions of Quantum Mechanics.
Or you can say that either Bell's (2 - locality or whatever you want to call it) and/or (14 - realism or whatever you want to call it) are wrong. Same thing.