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I think part of the problem (sociologically) is also sharp reluctance on part of funding agencies, and hiring committees. Graduate students are made to feel, in no uncertain terms, that working on quantum foundations equates to career suicide.

It’s like physicists (collectively) have PTSD from a few decades of trying to understand QM, which then crystallized into the maxim “shut up and calculate”. What we’re seeing is the resulting learned helplessness.

> The correct formulation involves the subtle concept of decoherence.

The trouble is that decoherence only explains part of the story. With decoherence you end up with the probability density converging into multiple outcomes. But decoherence does not in any way explain that the choice is made to pick one of these outcomes.

As for what is wrong with QM, the main issue for me is the measurement process, which is just posited axiomatically. How measurement works should be explained by the theory but it is just posited. They assume a classical device that does the measurement. Decoherence explains bits of it but much is left hanging loose.

In Scott Aaronson's paraphrased words...

Quantum mechanics is just statistics, but operations preserve the 2-norm instead of the 1-norm. Instead of case weights (probabilities) adding up to 1, the squares of case weights (amplitudes) add up to 1. Everything else (the uncertainty principle, measurement mattering, no cloning, Bell inequalities, etc, etc, etc) follows.

But how can one understand something in terms of some other, more basic, things when it itself is the most basic thing there is, save for the only language in which one can describe it in a meaningful way, math. We understand how atoms work, how semiconductors work, etc. - all in terms of quantum mechanics, but there is nothing else (but math) that can possibly “explain” how quantum mechanics itself “works” the way it does.

Granted, my PhD is in experimental physics, not theoretical. The story as I learned it was that QM is different because CM produced absurd answers for phenomena such as blackbody radiation, line spectra, and the photoelectric effect.

A good trick question is to ask them about the trace of noncommuting operators, if you have finite dimensions -

https://physics.stackexchange.com/questions/10230/trace-of-a...

>QM has uncertainty. Well... so does classical mechanics!

Wait what? I mean sure, at scale CM is not feasible to compute (eg. n body problem). But our inability to precisely compute the otherwise completely predictable events is not the same as QM which can give true randomness.

What in your view is the mechanism by which perfectly random outcomes are determined?

Well, either quantum needs fixing or GR does (or both). QM is extremely difficult to understand, GR is easier to grasp. I think it's a clue.

I agree that it needs better understanding, but to produce this understand would likely still require "fixing" it. As it stands, QM is a bunch of algebra that "works" for unspecified reasons when using some handwavey heuristics for converting CM to QM. It produces a miscellaneous set of implications, not all of which are clearly connected to each other.

Fundamentally, QM is just some special subset of algebra with certain properties. Just like other algebras aren't "physics", QM isn't really physics. It's just a bag of tools with the right algebraic features to solve a wide category of problems physicists often have.

This is fine, but first think of ordinary algebra. It has some interesting implications that took a while for people to wrap their head around. The zero wasn't a widely accepted concept for thousands of years. Negative numbers are already a squirrelly concept. How can you have negative three apples? That was an easy abstraction hurdle to get across, eventually, and now even children understand that the implication of this is that you owe three apples. If you're give five apples, you have to return three to whomever you borrowed apples from, and now you're left with two.

QM is firmly in the group of abstractions where we haven't worked out the mental models quite yet. Talking about complex-valued probabilities makes most people raise their eyebrows quizzically. It doesn't matter how many different ways you demonstrate that the algebra works out, it's still a very difficult concept to internalise.

One interesting mental model I've come across is that classical probabilities are the products of two things, we just haven't noticed. Quantum Mechanics undoes this multiplication, making it in some sense the "square root of classical probabilities", which is not a probability, but something... "else". It's mysterious because in ordinary life we only ever observe the (else×else) products, never the "roots", even though the latter is more fundamental.

I've never heard anyone take this kind of thought all the way to its conclusion. My current extremely tentative notion is that the "roots" represent probabilities in a kind of continuous alternate universe space, along the lines of MWI. Neither the "observer" nor the "observed" are in any one such universe, but smeared across them in some distribution. Their interactions require their many-worlds-distributions to be multiplied to produce a "real" result, which is still a distribution, but now the one we're used to in CM. Self-interactions such as a resonator in a potential well require self×self products, which are simplify to self^2. Quantum mechanics just undoes this squaring in order to model to underlying behaviour across parallel worlds.

But note how to get even this far, this tentative explanation already required a nearly complete rethinking of what QM really is. It's never going to be sufficient to shuffle the algebra around on a page, because algebra isn't physics. Physics is. Quantum Mechanics is still in the "a bunch of algebraic tricks" stage and needs to be dragged kicking and screaming into a form that people can intuitively understand in terms of physical concepts, not just mathematical ones.