This article should really be called "Patching the argumentative flaw in the Sequences created by the Quantum Physics Sequence".
There's only one big thing wrong with that Sequence: the central factual claim is wrong. I don't mean the claim that the Many Worlds interpretation is correct; I mean the claim that the Many Worlds interpretation is obviously correct. I don't agree with the ontological claim either, but I especially don't agree with the epistemological claim. It's a strawman which reduces the quantum debate to Everett versus Bohr - well, it's not really Bohr, since Bohr didn't believe wavefunctions were physical entities. Everett versus Collapse, then.
I've complained about this from the beginning, simply because I've also studied the topic and profoundly disagree with Eliezer's assessment. What I would like to see discussed on this occasion is not the physics, but rather how to patch the arguments in the Sequences that depend on this wrong sub-argument. To my eyes, this is a highly visible flaw, but it's not a deep one. It's a detail, a bug. Surely it affects nothing of substance.
However, before I proceed, I'd better back up my criticism. So: consider the existence of single-world retrocausal interpretations of quantum mechanics, such as John Cramer's transactional interpretation, which is descended from Wheeler-Feynman absorber theory. There are no superpositions, only causal chains running forward in time and backward in time. The calculus of complex-valued probability amplitudes is supposed to arise from this.
The existence of the retrocausal tradition already shows that the debate has been represented incorrectly; it should at least be Everett versus Bohr versus Cramer. I would also argue that when you look at the details, many-worlds has no discernible edge over single-world retrocausality:
- Relativity isn't an issue for the transactional interpretation: causality forwards and causality backwards are both local, it's the existence of loops in time which create the appearance of nonlocality.
- Retrocausal interpretations don't have an exact derivation of the Born rule, but neither does many-worlds.
- Many-worlds finds hope of such a derivation in a property of the quantum formalism: the resemblance of density matrix entries to probabilities. But single-world retrocausality finds such hope too: the Born probabilities can be obtained from the product of ψ with ψ*, its complex conjugate, and ψ* is the time reverse of ψ.
- Loops in time just fundamentally bug some people, but splitting worlds have the same effect on others.
I am not especially an advocate of retrocausal interpretations. They are among the possibilities; they deserve consideration and they get it. Retrocausality may or may not be an element of the real explanation of why quantum mechanics works. Progress towards the discovery of the truth requires exploration on many fronts, that's happening, we'll get there eventually. I have focused on retrocausal interpretations here just because they offer the clearest evidence that the big picture offered by the Sequence is wrong.
It's hopeless to suggest rewriting the Sequence, I don't think that would be a good use of anyone's time. But what I would like to have, is a clear idea of the role that "the winner is ... Many Worlds!" plays in the overall flow of argument, in the great meta-sequence that is Less Wrong's foundational text; and I would also like to have a clear idea of how to patch the argument, so that it routes around this flaw.
In the wiki, it states that "Cleaning up the old confusion about QM is used to introduce basic issues in rationality (such as the technical version of Occam's Razor), epistemology, reductionism, naturalism, and philosophy of science." So there we have it - a synopsis of the function that this Sequence is supposed to perform. Perhaps we need a working group that will identify each of the individual arguments, and come up with a substitute for each one.
A lot of the time, the rules aren't relativistic, just the input and output. MWI is a theory about what's inside the black box of reality: wavefunctions! Wavefunctions are what's real, it says. But the wavefunctions that actually get used in QFT are defined on a preferred time-slicing (closed time-path formalism), or they only exist asymptotically, in the infinite past or future (S-matrix)... The mathematical manipulations in QFT can be quite baroque, and I am very far from seeing how you could make them all relativistic at every stage.
The only way I can see to do it, is to break the theory down to the level of individual space-time points, allow continua of duplicates of points, define the analogue of Lorentz transformations in the resulting infinite-dimensional space, and then define a way to build the configurations (that enter into a wavefunctional in the position basis) out of these points, while also associating amplitudes or proto-amplitudes with the way that the points are glued together, so that configurations can have global amplitudes attached to them as required. It would be a sort of bottom-up approach to the "spacetime state realism" described by Wallace and Timpson, and it might not even be a well-defined approach for a QFT that isn't UV-complete, like QED.
That was all a mouthful to say, and I regret introducing such complexity into the discussion, but that is how I think when I ask myself "how could you describe a quantum multiverse that is genuinely relativistic?" To ontologically ground QFT, you have to specify what it is that exists in the ontology, and you have to explain what the QFT calculational procedures mean ontologically - why they work, what real things they refer to. And if you're going to ground it all in wavefunctions, and you don't want to be stuck in a preferred frame, then you have to do something drastic.
When you describe a state, you need to choose a method of describing it, yes. But you can choose to describe it in any frame you like, and you can transform from one such description to another in a different frame. This is an artifact of the descriptions, not the thing in itself.
Like, you have a covariant quantity. You can do all sorts of symbolic math with it a... (read more)