There was the so-called "proton spin crisis" or "nucleon spin crisis" b/c we were not able to explain the total proton spin based on some simple QCD mechanism ("valence quark spin"). Meanwhile the measurement of so-called polarized nucleon structure functions is much more accurate; in addition we have better models (again based on QCD) which allow us to take other contributions (gluon spin, quark and gluon angular momentum) into account. Afaik based on these considerations the nucleon spin can be explained pretty well.kurros said:The proton spin comes from the sum of the spins of the quarks inside. Is there something weird about it that I don't know?
Agreed.humanino said:I would definitely not count the spin proton "puzzle" as "something wrong" with the standard model. You can only count it as a fundamental issue if you consider that we have something to understand about non-perturbative gauge theory (say AdS/QCD for instance, or "gravity as the square of a gauge theory"). [/url]
The problem is the following. Assume you were able to identify a new and elegant structure. How would you "break" this elegance and create the awfull standard model? I mean, in the end the standard model (the its physics) must emerge b/c we see it in experiments.Oldfart said:From the bottom basement of my physics knowledge, I await an enormous simplification of the standard model. All of its complications seem to be too complicated to be real, as though they are derived to suit experimental results that no one fully understands. I'm not knocking the science behind the standard model, just looking for something much simpler.
tom.stoer said:The problem is the following. Assume you were able to identify a new and elegant structure. How would you "break" this elegance and create the awfull standard model? I mean, in the end the standard model (the its physics) must emerge b/c we see it in experiments.
Look at Supersymmetry. The theories look rather nice and highly symmetric. Unfortunately we do not observe SUSY in nature, therefore the conclusion is that SUSY has to be broken at low energies. In order to do that you have to introduce Higgs bosons (plus SUSY-partners) and all elegance is ruined. The same applies to highly symmetric GUTs like SU(5) or SO(10). In the beginning the structure is nice but as soon as you want them to agree with nature you have to introduce some symmetry breaking which spoils its elegance.
Regardless which structure you may find, there must be some obscure mechanism which creates all the low-energy mess.
The Standard Model is a theory in particle physics that describes the fundamental particles and their interactions through three of the four fundamental forces: electromagnetism, weak nuclear force, and strong nuclear force. It has been extremely successful in predicting and explaining many phenomena in the subatomic world.
The Standard Model is unable to explain gravity, which is the fourth fundamental force. It also does not account for dark matter, which is believed to make up a large portion of the universe's mass. Additionally, it cannot explain why there is more matter than antimatter in the universe.
The hierarchy problem refers to the large discrepancy between the energy scales of the weak nuclear force and gravity. According to the Standard Model, these energy scales should be similar, but in reality, the weak nuclear force is much stronger. This problem has led scientists to believe that there must be some new physics beyond the Standard Model.
The Standard Model explains mass through the Higgs mechanism, which proposes the existence of a Higgs field and particle. The Higgs field interacts with particles, giving them mass. However, the Standard Model cannot explain the exact mass values of particles, and the Higgs boson's mass is much lighter than expected.
Some theories that aim to go beyond the Standard Model include supersymmetry, which proposes the existence of new particles that could solve the hierarchy problem and explain dark matter. Other theories include extra dimensions, grand unified theories, and string theory, all of which attempt to unify the fundamental forces and particles in a more comprehensive framework.