Quantum Wittgenstein

[Magical Realist]

https://aeon.co/essays/how-wittgenstein-...um-physics

"By the late 20th century, dozens of other interpretations had appeared under exotic names: the many-worlds theory, superdeterminism, consistent histories, the modal interpretation, superselection, Bohmian mechanics, Lindblad equations. I even invented my own: dynamic histories. While a few, like mine, proposed new theories that could come into conflict with quantum mechanics, most of them don’t. They are metaphysical, not physical.

The big question lurking behind all this is: what does the wavefunction mean? Does it represent something real or not? Most interpretations are ‘realist’ in the sense that they assume the wavefunction is a real entity and then go on to explain what it represents – but a few say it doesn’t exist at all, such as Quantum Bayesianism or QBism, as it is known. QBism owes its existence to the work of Wittgenstein’s friend and contemporary Frank Ramsey, who developed an anti-realist interpretation of probability. QBism holds that the wavefunction is purely an encoding of human uncertainty, representing a spectrum of probabilities that is updated when we make an observation. So the quantum wavefunction is not about objective reality at all, but about our future observations. QBism therefore refutes the Platonic idealism of the wavefunction and declares it to be a mere mathematical quantification of our beliefs.

Plenty of physicists have grown tired of this debate and its seemingly endless and unsatisfying arguments between realists and anti-realists. They want us to ‘Shut up and calculate!’ in the words of the physicist David Mermin: to stop trying to interpret quantum mechanics at all and get back to doing it. Philosophers, on the other hand, tend to dismiss this latter group as being philosophically ignorant. There’s a suspicion that, deep down, such physicists simply possess a metaphysics that they don’t want to admit, because they don’t want to come down on the side of an interpretation that has no scientific backing.

Yet those who follow Mermin’s injuction have a friend in one of the great philosophical minds of the 20th century – one who provides not only support for their position, but philosophical reasoning for why it is the only correct one..."

[C C]

Four ways to interpret quantum mechanics
https://cerncourier.com/a/four-ways-to-i...mechanics/

INTRO: Orthodox quantum mechanics is empirically flawless, but founded on an awkward interface between quantum systems and classical probes. In this feature, Carlo Rovelli – himself the originator of the relational interpretation – describes the major schools of thought on how to make sense of a purely quantum world.

EXCERPTS: Today, variants of four main ideas stand at the forefront of efforts to make quantum mechanics more conceptually robust. They are known as physical collapse, hidden variables, many worlds and relational quantum mechanics. Each appears to me to be viable a priori, but each comes with a conceptual price to pay. The latter two may be of particular interest to the high-energy community as the first two do not appear to fit well with relativity.

The idea of the physical collapse is simple [...] So far, all laboratory attempts to find violations of the textbook Schrödinger equation have failed, and some models for these hypothetical new dynamics have been ruled out by measurements.

The second possibility, hidden variables, [...] posits that its predictions are exactly correct, but that there are additional variables describing what is going on...

[...] Let me now come to the two ideas that are naturally closer to relativistic physics. The first is the many-worlds interpretation – a way of making sense of quantum theory without either changing its dynamics or adding extra variables. ... The price to pay to make sense of quantum theory in this manner is to accept the idea that the reality we see is just a branch in a vast collection of possible worlds that include innumerable copies of ourselves.

[...] Relational interpretations are the most recent of the four kinds mentioned. They similarly avoid physical collapse or hidden variables, but do so without multiplying worlds. They stay closer to the orthodox textbook interpretation, but with no privileged status for observers.

[...] The relational interpretation reduces the content of the physical theory to be about how systems affect other systems. This is like the orthodox textbook interpretation, but made democratic. Instead of a preferred classical world, any system can play a role that is a generalisation of the Copenhagen observer. Relativity teaches us that velocity is a relative concept: an object has no velocity by itself, but only relative to another object. Similarly, quantum mechanics, interpreted in this manner, teaches us that all physical variables are relative. They are not properties of a single object, but ways in which an object affects another object.

The QBism version of the interpretation restricts its attention to observing systems that are rational agents...

[...] Like many worlds – to which it is not unrelated – the relational interpretation does not add new dynamics or new variables. Unlike many worlds, it does not ask us to think about parallel worlds either. The conceptual price to pay is a radical weakening of a strong form of realism

[...] Only quantum states of a system relative to another system play a role in this interpretation. The many-worlds interpretation is very close to this. ... In this sense, the many worlds and relational interpretations can be seen as two sides of the same coin.

[...] I have only sketched here the most discussed alternatives, and have tried to be as neutral as possible in a field of lively debates in which I have my own strong bias (towards the fourth solution). Empirical testing, as I have mentioned, can only test the physical collapse hypothesis.

There is nothing wrong, in science, in using different pictures for the same phenomenon. Conceptual flexibility is itself a resource. Specific interpretations often turn out to be well adapted to specific problems...

[...] Richard Feynman famously wrote that “every theoretical physicist who is any good knows six or seven different theoretical representations for exactly the same physics. He knows that they are all equivalent, and that nobody is ever going to be able to decide which one is right at that level, but he keeps them in his head, hoping that they will give him different ideas for guessing.”

I think that this is where we are, in trying to make sense of our best physical theory. We have various ways to make sense of it. We do not yet know which of these will turn out to be the most fruitful in the future... (MORE - missing details)