https://physics.stackexchange.com/questions/106392/internal-and-spacetime-symmetries

The different only shows up for <field (physics)>, not with particles. For fields, there are two types of changes that we can make that can keep the <Lagrangian> unchanged as mentioned at <Physics from Symmetry by Jakob Schwichtenberg (2015)> chapter "4.5.2 Noether's Theorem for Field Theories - Spacetime":
* <spacetime symmetry>: act with the <Poincaré group> on the <Four-vector> spacetime inputs of the field itself, i.e. transforming $L(\Phi(x), \partial \Phi(x), dx)$ into $L(\Phi'(x'), \partial \Phi'(x'), x')$
* <internal symmetry>: act on the output of the  field, i.e.: $L(\Phi(x) + \delta \Phi(x), \partial (\Phi(x) + \delta \Phi(x)), x)$

From <defining properties of elementary particles>:
* spacetime:
  * <mass>
  * <spin (physics)>
* internal
  * <electric charge>
  * <Weak charge>
  * <color charge>

From the spacetime theory alone, we can derive the <Lagrangian> for the free theories for each <spin (physics)>:
* <spin 0>: <Klein-Gordon equation>
* <spin half>: <Dirac equation>
* <spin 1>: <Proca equation>
Then the internal symmetries are what add the interaction part of the <Lagrangian>, which then completes the <Standard Model Lagrangian>.


Internal and spacetime symmetries

{disambiguate=physics}

= Spin
{synonym}

Spin is one of the <defining properties of elementary particles>, i.e. number that describes how an <elementary particle> behaves, much like <electric charge> and <mass>.

Possible values are half integer numbers: 0, 1/2, 1, 3/2, and so on.

The approach shown in this section: <spin comes naturally when adding relativity to quantum mechanics>{full} shows what the spin number actually means in general. As shown there, the spin number it is a direct consequence of having the laws of nature be <Lorentz invariant>. Different spin numbers are just different ways in which this can be achieved as per different <Representation of the Lorentz group>.

<video Quantum Mechanics 9a - Photon Spin and Schrodinger's Cat I by ViaScience (2013)> explains nicely how:
* incorporated into the <Dirac equation> as a natural consequence of <special relativity> corrections, but not naturally present in the <Schrödinger equation>, see also: <the Dirac equation predicts spin>
* <photon> spin can be either linear or circular
* the linear one can be made from a superposition of circular ones
* straight antennas produce linearly polarized photos, and https://en.wikipedia.org/wiki/Helical_antenna[Helical antennas] circularly polarized ones
* a jump between 2s and 2p in an atom changes angular momentum. Therefore, the photon must carry angular momentum as well as energy.
* cannot be classically explained, because even for a very large estimate of the electron size, its surface would have to spin faster than light to achieve that magnetic momentum with the known <electron charge>
* as shown at <video Quantum Mechanics 12b - Dirac Equation II by ViaScience (2015)>, observers in different <frame of reference>[frames of reference] see different spin states

\Video[https://www.youtube.com/watch?v=6sR6RV2znXI]
{title=Quantum Mechanics 9a - Photon Spin and Schrodinger's Cat I by <ViaScience> (2013)}

\Video[https://www.youtube.com/watch?v=3k5IWlVdMbo]
{title=Quantum Spin - Visualizing the physics and mathematics by <Physics Videos by Eugene Khutoryansky> (2016)}

\Video[https://www.youtube.com/watch?v=AToXA0Molig]
{title=Understanding QFT - Episode 1 by Highly Entropic Mind (2023)}
{description=Maybe he stands a chance.}


Ciro Santilli @cirosantilli 35

 Incoming links: Defining properties of elementary particles