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advanced_notions:elementary_particles [2017/10/08 16:55]
jakobadmin ↷ Page moved from standard_model:elementary_particles to advanced_notions:elementary_particles
advanced_notions:elementary_particles [2018/04/14 10:08] (current)
aresmarrero [Abstract]
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 ====== Elementary Particles ====== ====== Elementary Particles ======
  
-<tabbox Why is it interesting?> ​ 
- 
-<tabbox Layman?> ​ 
  
-[[http://​www.ejsme.net/​articles/​52/​523.pdf|Why not start with quarks? Teachers investigate a learning unit on +<tabbox Intuitive> ​
-the subatomic structure of matter with 12-year-olds]] by Gerfried J. Wiener, Sascha M. Schmeling and Martin Hopf+
  
 +  * A nice overview is given here: https://​profmattstrassler.com/​articles-and-posts/​particle-physics-basics/​the-known-apparently-elementary-particles/​
 +  * [[http://​www.ejsme.net/​articles/​52/​523.pdf|Why not start with quarks? Teachers investigate a learning unit on the subatomic structure of matter with 12-year-olds]] by Gerfried J. Wiener, Sascha M. Schmeling and Martin Hopf
 +  * [[https://​gravityandlevity.wordpress.com/​2015/​04/​11/​how-big-is-an-electron/​|How big is an electron?]] by Brian Skinner
  
   ​   ​
-<​tabbox ​Student+<​tabbox ​Concrete 
 +{{ :​advanced_notions:​elemparticles.png?​nolink |}} 
 + 
 +---- 
 <​blockquote>​ <​blockquote>​
 In the 1970’s, high energy physicists pursued Lie algebra theory as a valuable tool to characterize all the gauge interactions. These are now understood to be SU(3) for the strong force (which describes the interacations between quarks, which are the constituents of hadrons such as the proton), and SU(2) × U(1) for both the weak and electromagnetic interactions of quarks and leptons (such as the electron). This is an important feature of the standard model of particle physics [YM,​We,​Sa,​Gl]. Grand unification was an effort to combine these symmetries as subgroups of a unifying group such as SU(5). Superstring unification provides an alternative mechanism to combine symmetries. In the 1970’s, high energy physicists pursued Lie algebra theory as a valuable tool to characterize all the gauge interactions. These are now understood to be SU(3) for the strong force (which describes the interacations between quarks, which are the constituents of hadrons such as the proton), and SU(2) × U(1) for both the weak and electromagnetic interactions of quarks and leptons (such as the electron). This is an important feature of the standard model of particle physics [YM,​We,​Sa,​Gl]. Grand unification was an effort to combine these symmetries as subgroups of a unifying group such as SU(5). Superstring unification provides an alternative mechanism to combine symmetries.
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 <​cite>​http://​thep.housing.rug.nl/​sites/​default/​files/​theses/​Master%20thesis_Marco%20Boers.pdf</​cite>​ <​cite>​http://​thep.housing.rug.nl/​sites/​default/​files/​theses/​Master%20thesis_Marco%20Boers.pdf</​cite>​
 </​blockquote>​ </​blockquote>​
-<​tabbox ​Researcher+ 
 +<​tabbox ​Abstract 
 +<​blockquote>​A question not often addressed when discussing the standard model is how one describes physical 
 +particles. Taking the electron as an example, the assumption usually made is that the free Dirac 
 +spinor in the interacting theory, at asymptotic times, can be viewed as an electron since ‘the coupling 
 +switches off’. This would mean that what is being caught in a detector is really a free fermion. The 
 +problem here, of course, is that in QED and QCD the coupling does not switch off, and assuming 
 +it does so generates infrared divergences. As a result, the spinors do not become free even at 
 +asymptotic times [1, 2], nor do they ever become gauge invariant. [...] 
 + 
 + The physical picture is of a matter particle 
 +surrounded by a cloud of ‘photons’,​ neither of which are individually observable, but which together 
 +constitute a gauge invariant, physical particle. This description is nonlocal, which is an immediate 
 +consequence of gauge invariance, but observables calculated with our states are manifestly local and 
 +correctly reproduce classically expected physics. 
 + 
 +<​cite>​[[https://​arxiv.org/​abs/​0907.4071|Stability,​ creation and annihilation of charges in gauge theories]] by Anton Ilderton, Martin Lavelle, David McMullan</​cite>​ 
 + 
 + 
 +</​blockquote>​ 
 + 
 +----- 
 + 
 +  * http://​math.ucr.edu/​home/​baez/​qg-spring2003/​elementary/​ 
 +  * See http://​physics.stackexchange.com/​questions/​33350/​particle-as-a-representation-of-the-lorentz-group 
 +  * [[http://​www.pnas.org/​content/​99/​1/​33.full.pdf|A closer look at the elementary fermions]] by Maurice Goldhaber 
 + 
 +-----
  
 <​blockquote>​ <​blockquote>​
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 </​blockquote>​ </​blockquote>​
  
-   +<​tabbox ​Why is it interesting?​
-<​tabbox ​Examples+
  
---Example1#+Elementary particles are the fundamental building blocks and also responsible for the fundamental interactions like electromagnetism. 
 +<tabbox FAQ
  
-  +--> How large is an elementary particle?#
-<--+
  
---> Example2:#+See https://​axelmaas.blogspot.de/​2018/​02/​how-large-is-elementary-particle.html?​m=1 
 +<--
  
- +-->Why do physicists believe that particles are pointlike?#​ 
 +see https://​physics.stackexchange.com/​questions/​41676/​why-do-physicists-believe-that-particles-are-pointlike
 <-- <--
   ​   ​
advanced_notions/elementary_particles.1507474557.txt.gz · Last modified: 2017/12/04 08:01 (external edit)