QFT is too successful that experimentalists stuck for half a century with no meaningful surprise. But theoreticians got to maintain a publication streak if trying to stay in academy. Thus string theory becomes the perfect field. Most ones doing it seem to know it is a goose chase but no one dare to admit it publicly as your colleagues stripped of funding would tear you to pieces.

I feel we really should sort these papers into a category "physics in imaginary universe", so other people do not get confused.

> QFT is one of the most successful theories we've created, but GR is still our best theory regarding gravity. There's still no evidence for the graviton. We probably need something else besides QFT to describe the nature of reality

The evidence for QFT is orders of magnitude stronger than the evidence for GR, and the two are incompatible. The empirical evidence is simply the fact that gravity exists; if there's no graviton then how does gravity work? If the right model isn't one of the (obscenely many) possible string theories, then what?

I'm sceptical about string theory, but unless and until we come up with a better alternative, it's the only option. (People love to compare it with epicycles - but until you have the insight that lets you eliminate epicycles, you use them, because how else do you get on with doing science?)

> The empirical evidence is simply the fact that gravity exists; if there's no graviton then how does gravity work?

According to GR, gravity per se is a kind of illusion caused by the movement of particles in a curved space-time. The more basic effect is spacetime curving itself around mass(/energy).

Now, whether this interaction itself is quantized or not (if the curvature comes in integer multiples) remains unknown. It is very much possible that gravity/space-time curvature is a different kind of effect than the other three fundamental interactions, and that it is not in fact qunatized, so there is no graviton.

And unto string theory, the problem with it is that it doesn't explain anything new. It posits some ideas of how gravity might work in a qunatized form, but any actual tests of the correctness of those calculations requires studying a black hole up close, which won't happen very soon. And of course, it infamously does so at the cost of adding lots of new elements to physics (extra dimensions, extra particles) none of which are testable or observed. And it still doesn't fix other problems of QM/QFT, most notably the measurement problem.

Plus, there is no actual need for String Theory to say that it's the best option we've got for X. For whatever we want to model, we can use either QFT or GR.

> According to GR, gravity per se is a kind of illusion caused by the movement of particles in a curved space-time. The more basic effect is spacetime curving itself around mass(/energy).

Right, but you can't actually do physics (that is, QFT) in that model. You can model a universe made up of particles that have mass and no other properties, and, uh, that's it.

> Now, whether this interaction itself is quantized or not (if the curvature comes in integer multiples) remains unknown. It is very much possible that gravity/space-time curvature is a different kind of effect than the other three fundamental interactions, and that it is not in fact qunatized, so there is no graviton.

I mean, yes, but in that case what is it? I would love for someone to come up with a non-graviton model that describes gravity while remaining compatible with QFT. But unless and until someone actually comes up with that model, gravitons are the best we can do.

> And unto string theory, the problem with it is that it doesn't explain anything new. It posits some ideas of how gravity might work in a qunatized form, but any actual tests of the correctness of those calculations requires studying a black hole up close, which won't happen very soon.

Directly observing both mass and non-mass aspects of particles at the same time is hard, sure. But we know that particles exist and have both mass and charge (and colour and all that)! They must in fact be subject to both QFT and gravitational effects at the same time. Yes, I can't immediately show that up on my desk in the lab, but I'm deeply uncomfortable with "ignore gravity unless you're working with big stuff, and then if you're working with big stuff ignore the whole rest of known physics and use this radically different theory (that, again, fundamentally contradicts the entire rest of known physics) to model what it's doing". I mean, yes, it does work for all the experiments we can currently do. But it's not at all a satisfactory model of how the universe actually works.

> then what?

Then it us a "simulation". "Pixels" of reality rendering.

And? That doesn't explain anything. What rules is the "simulation" following? If it's not following any, how come reality behaves so consistently in most respects?

Simulation theory is not my invention, actual scientists have tested it and theorized with strong evidence.

I would answer your question but not worth the downvotes like my original comment.

I don't remember any evidence supporting the simulation theory. Do you have a link?

I wouldn't say empirical evidence but here is one of many that keeps popping up in popsci news: https://www.scientificamerican.com/article/confirmed-we-live...

That article is an April Fools joke.

The simulation hypothesis is nothing except sciencey-sounding creationism/dualism.

That sounds good, but after reading it carefully it makes no sense. It was posted in April 1 2021.