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anoncareer0212 | 10 months ago
When we get new theory, then we go hunting new particles, presuming its physically possible (as you point out with the incorrect idea that this might be being built to look for confirmation of string theory)
I understand the idea this won't find new particles, is it worth it?, but the idea this is unclear, confusing, misguided, or hoping for an outcome are trivially verifiable as false.
Things like:
- "The scientific goals...are unclear" (they are very clear!)
- "(modulo some error)" (reducing the error in the glimpses of deviation from the standard model is the interesting part, 5 sigma or bust, because that lets the theorists know how to progress. This isn't just "oh we'd like to reduce error bars, a less-entitled discipline would just get some grad students on SPSS", this is "holy shit...looks like we found something is fucky in our fundamentals here, but all we know is its off. we need to figure out by how much to give the theorists more data")
- "string theory et al" (I worry very much about the effectiveness of my communication if this is coming up, to be clear, no one is attempting to verify string theory, and it doesn't come up at all even in Sabine's arguments, no? )
The IEEE article lays out this is not about discovering particles.
No one thinks new particles will be discovered.
The investment is not based on speculating new particles will be discovered.
The investment is not based on bad theory that new particles will be discovered.
The investment is not to find a sneaky way to hopefully accidentally find new particles.
Investments in colliders in general haven't been spectulatively looking for new particles in decades.
As both the IEEE, open source information, and my comment lay out above, they are specifically for nailing down these previously-assumed-settled values in the standard model. Because getting more data on the things theory can't explain leads to informed revisions in the theory. The next pendulum swing after that data would be theory to tell us a narrow band of energies to look at for any new particles theory needed to fix the standard model.
pclmulqdq|10 months ago
The error they saw isn't interesting unless it leads to something. There aren't even good theories about what it might lead to, other than some extra significant figures on some constants that nobody uses. Surely you can see there is a problem with doing science this way.
Theory precedes experiment. It always has, and you can't call what you're doing "science" unless that is true.
77pt77|10 months ago
This is laughably false, even in fundamental physics.
No one saw neutrinos coming for example.
unknown|10 months ago
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tsimionescu|10 months ago
Blatantly false. Plenty of FCC docs from CERN itself mention the possibility that new particles could be discovered, from dark matter to axions. They even think they could help gather data to guide searches for supersymmetric partners.
[edited to add links and quotes]
https://fcc-cdr.web.cern.ch/reports/EPPSU18_FCCint.pdf
> In addition to the dark matter examples given before, Volume 1 documents the extraordinary sensitivity to less-than-weakly coupled particles, ranging from heavy sterile neutrinos (see Fig. 5, right) down to the see-saw limit in a part of parameter space favourable for generating the baryon asymmetry of the Universe, to axions and dark photons.
https://fcc.web.cern.ch/physics
> Future searches at lepton and proton colliders would further constrain any viable scenarios and put progressively tighter bounds to SUSY candidate particles. Searches could profit from data collected at the FCCs as they will allow better discrimination of the Standard Model backgrounds but also deliver more information for event reconstruction.
pclmulqdq|10 months ago
There's lots of "could" in your own post and your sources. Very little "will" - as in "will test X theory."