What do we mean by spin of a particle when we say it a point particle

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Discussion Overview

The discussion focuses on the concept of spin in quantum mechanics, particularly in relation to point particles. Participants explore how spin is defined, measured, and its implications in physics, including the distinction between different spin values and the nature of spin-0 particles. The conversation touches on theoretical and conceptual aspects of spin, as well as its experimental measurement.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • Some participants question the meaning of spin for point particles and how it can be measured experimentally, noting the assignment of values like +1, +2, etc.
  • It is suggested that the concept of spin cannot be visualized in classical terms, as attempts to do so lead to inconsistencies, such as exceeding the speed of light.
  • One participant explains that the wave function of a particle is unchanged when rotated by specific angles, linking this to the particle's spin value.
  • There is a discussion about the necessity of including spin in particle physics to accurately describe phenomena, such as the behavior of electrons in atomic shells.
  • Some participants express confusion about the relevance of spin, with one stating it is merely a label for a property, similar to strangeness or charm in quarks.
  • Others clarify that "spin" refers to intrinsic angular momentum and contributes to macroscopic angular momentum, referencing the Einstein-DeHaas effect.
  • A participant emphasizes that quantum mechanical descriptions of spin cannot be understood through classical analogies.
  • There are repeated inquiries about what is meant by the "something" that electrons do when they "spin," with responses indicating a lack of complete understanding of the underlying mechanics.
  • One participant suggests that quantum spin is a fundamental property, akin to mass and charge, rather than something that can be accurately depicted with classical examples.

Areas of Agreement / Disagreement

Participants express a range of views on the nature and significance of spin, with no consensus reached on its interpretation or the necessity of its inclusion in discussions of particle physics. Some participants find the concept essential, while others question its relevance.

Contextual Notes

The discussion reveals limitations in understanding spin, particularly regarding its visualization and the classical analogies often employed. There are unresolved questions about the fundamental nature of spin and its implications in quantum mechanics.

nouveau_riche
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what do we mean by spin of a particle when we say it a point particle?how do we measure spin experimentally and give it values like +1,+2 etc.
what does it mean by a spin 0 particle?
 
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The problem which occurs in understanding spin stems from our lack of visualization within the classical world in this regards. Spin of a particle cannot be understood as a spinning point particle. That idea was shown to be inconsistent as any such attempt will make the surface speed of the particle exceed the speed of light or make it larger than the current bounds (even if you want to think about it as a point particle, which itself is of limited value within the quantum world where the spinning property of particle belongs). However, the behavior of particle in an external influence such as magnetic field can only be explained if the particles have a intrinsic spin. Regardless of the lack of visualization, in the classical sense, the name "spin" for this property of particles has survived through the ages.

As far as the question of measurement and subsequent quantization of Spin is concerned I will agree with Simon that you can find tons of information on this in any undergraduate book on Quantum Mechanics.

Good luck!
 
nouveau_riche said:
what do we mean by spin of a particle when we say it a point particle?how do we measure spin experimentally and give it values like +1,+2 etc.
what does it mean by a spin 0 particle?

If the wave function of a particle is unchanged when rotated by 2π/s radians, the particle has spin s. For example photon has spin 1, thus its wave function is unchanged when rotated by 2π (360 degrees, or one full revolution around an axis). Electron has spin 1/2, so you need to rotate its wave function twice around the axis (720 degrees) to get the same wave function. If a particle has spin 2, it is sufficient to rotate it by 180 degrees to get the same wave function.

Fields with spin 0 are scalar, fields with spin 1 are vector fields, fields with spin 2 are tensor fields.
 
mpv_plate said:
If the wave function of a particle is unchanged when rotated by 2π/s radians, the particle has spin s. For example photon has spin 1, thus its wave function is unchanged when rotated by 2π (360 degrees, or one full revolution around an axis). Electron has spin 1/2, so you need to rotate its wave function twice around the axis (720 degrees) to get the same wave function. If a particle has spin 2, it is sufficient to rotate it by 180 degrees to get the same wave function.

Fields with spin 0 are scalar, fields with spin 1 are vector fields, fields with spin 2 are tensor fields.

i am not getting the reason to bring the concept of spin
 


nouveau_riche said:
i am not getting the reason to include the concept of spin

Well, without this additional degree of freedom, it would not be possible of accurately describe many things. How about the number of electrons in different atomic shells? Or behavior of particles with known spin?

The point being that spin needs to be included to properly explain various particle behavior.
 
When we talk about "spin", we really don't mean spin. We talk about charged electrons doing "something" that has a similar effect as if they are spinning. You can name it any thing else, but that's another thing (we don't know what that electrons do, when they "spin").
 
"Spin" in QM is shorthand for "intrinsic angular momentum." We know it's angular momentum because it contributes to an object's total macroscopic angular momentum. See the Einstein-DeHaas effect.
 
  • #10
Kholdstare said:
When we talk about "spin", we really don't mean spin. We talk about charged electrons doing "something" that has a similar effect as if they are spinning. You can name it any thing else, but that's another thing (we don't know what that electrons do, when they "spin").

what is that "something" you are talking about?
 
  • #11
nouveau_riche said:
what is that "something" you are talking about?

I told you already. Electrons obey quantum mechanics and the quantum mechanical description of spin can not be understood by drawing analogy between that and the classical concept of spin.
 
  • #12
nouveau_riche said:
what is that "something" you are talking about?

He already gave you the best current answer to this question:

Kholdstare said:
(we don't know what that electrons do, when they "spin").

All we can do is calculate the effects of "spin" on things that we can actually measure.
 
  • #13


nouveau_riche said:
i am not getting the reason to include the concept of spin

It is a name for a property... like strangeness or charm for quarks. In this case chosen for the similarity in the math and its relationship to things like moment of inertia and magnetic moment. A name does not have to mean anything: it's just a handy label.
 
  • #14
jtbell said:
"Spin" in QM is shorthand for "intrinsic angular momentum." We know it's angular momentum because it contributes to an object's total macroscopic angular momentum. See the Einstein-DeHaas effect.

could you please show me what you said, with an example
 
  • #16
Imagine a ball that is spinning and think about how it would move. Now imagine its not a ball and not spinning. That what quantum particles are like, but they still have the interactions with other particles similar to those which the spinning ball would have.

If you bounce a spinning ball it will deflect from the floor (or whatever it hits) and move off in a different direction. There is no exact analogy, but electrons will have their paths changed in a way that makes sense if one assumes they have the same mathematical trait that a spinning ball has (angular momentum). But they are not balls and they are not spinning, so it is just a trait that they intrinsically have.

This may not be satisfying, but none of us can do anything about that.
 
  • #17
nouveau_riche said:
could you please show me what you said, with an example

There is no way to give you a picture of quantum spin that would be accurate. It simply has no analog with classical physics. Instead I suggest thinking of it as a fundamental property of a particle, like mass and charge are. Personally I view angular momentum and spinning at the macroscopic level as an imitation of the quantum property, like how mass adds up with each particle that makes up an object.
 

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