Angular and magnetic momentum

In summary: Without a magnetic field, the angular momentum would be conserved.This means that the angular momentum would always point in the same direction.This is deduced from the equations of conservation of angular momentum.
  • #36
The proton, like any hadron, is understood in terms of it's constituent quarks - each of which have an intrinsic spin. Protons are not well modeled as classically rotating objects.

Protons are also "Fermions", they have half-integer spin just like electrons.
At your level you will have only had a glimpse of the standard model of particle physics ... which is a huge subject all by itself.

We have to be very careful about what we call "real" in quantum mechanics ... the usual definition is that it is real if you can measure it. Intrinsic spin is real angular momentum in the sense that we can measure it and it gives rise to rotations that we can measure.
 
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  • #37
Simon Bridge said:
Intrinsic spin is real angular momentum in the sense that we can measure it ...
Protons are also "Fermions", they have half-integer spin just like electrons.
.
But the proton is really spinning on its internal axis, the electron makes it spin,right?
So, is the total angular momentum of 1H ([itex]\hbar[/itex]+1/2+1/2) =2 [itex]\hbar[/itex] =h/[itex]\pi[/itex]?
 
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  • #38
No. You should be able to look that stuff up ;)
Note: electrons in an atom have orbital angular momentum as well as spin.
 
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  • #39
Simon Bridge said:
electrons in an atom have orbital angular momentum as well as spin.
bobie said:
So, is the total angular momentum of 1H ([itex]\hbar[/itex]+1/2+1/2) =2 [itex]\hbar[/itex] =h/[itex]\pi[/itex]?
I have considered Lorbit = [itex]\hbar[/itex]
According to what you said I considered a
vector at the nucleus : Lo = [itex]\hbar[/itex] + Lp (you said) =1/2 [itex]\hbar[/itex] =3/2 [itex]\hbar[/itex]
Ant the vector of the spin at the electron Le = 1/2 [itex]\hbar[/itex]
So the total momentum of the 1H atom should be 3/2+1/2 = 2 [itex]\hbar[/itex]= h/[itex]\pi[/itex]

I have read that the the spin being 1/2 implies the electron behaving like on a Moebius strip, is that true? why so?
if it where ,say, 32 couldn't it run on a Moebius strip?
 
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  • #40
I have read...
...where?!

...that the the spin being 1/2 implies the electron behaving like on a Moebius strip...
... in what way? "like" is such a vague term.
Sounds like a reference to Dirac's Plate Trick
http://en.wikipedia.org/wiki/Plate_trick

Also see:
http://scienceblogs.com/principles/2010/07/26/electron-spin-for-toddlers/
... since it is still bothering you.

Hydrogen:
http://en.wikipedia.org/wiki/Hydrogen_atom#Angular_momentum
... when you are thinking of the angular momentum of an atom, you have to consider what state it is in.
Usually you want to do this for the ground state.

https://www.physicsforums.com/showthread.php?t=69992

Beware of articles which go out of their way to make QM sound weird and mysterious.
That would include most pop-science and about 99% of the material found on the Discovery Channel.
 
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  • #41
Simon Bridge said:
Usually you want to do this for the ground state.
Beware of articles which go out of their way to make QM sound weird and mysterious.
.
Thanks for the precious links, Simon. I'm trying to do my homework.
What I meant is:
1/2 [itex]\hbar[/itex] it's just a numerical value, it could be 2π [itex]\hbar[/itex] or 32 or anything.
Why does this particular value determine the fact that it rotates twice before pointing in the same direction? or I misinterpreted the article? how do we notice that it rotates by 720°?

- I read that in ground state 1s there is no angular momentum, this being one of the main differences from Bohr's model, is this true?
- if so, as there is no pseudovector L(o) and no plane of an orbit xy, how can we detect the spin component on z? if there is no xy where is z?
- I do not think QM is weird, but it seems to have rules that cannot be verified and contradict the rules outside the atom. It's difficult to know where it is just theory.

Thanks.
 
  • #42
The value of angular momentum is not arbitrary if that's what you mean.
It is determined empirically and there is a deeper mathematical model that makes sense of it.
Right now you are exploring the results of that model.

The value assigned to mean a particular symmetry is arbitrary though, and there are several schemes.
So you could be asking "why use that particular scheme?"

Consider:
It would be natural and intuitive, for many people, to classify rotational symmetry by the angle A you have to rotate through for the object to map on to itself. It's not nice to use this method in practice (give it a go) because you really want more symmetry to mean a bigger number and you want to avoid fractions if you can help it. But to see how that may work we have to be careful about what we mean when we talk about angles.

The angle is the pointy bit in a corner - the size of the angle would be the inverse of it's sharpness. The less pointy the corner, the bigger the angle.

The size of the angle is most conveniently defined on the unit circle as follows - the length of the circumference of the unit circle that lies inside the angle is called "the size of the angle". But that begs the question of the definition of the unit circle.

A unit circle may be defined with the radius, diameter, or circumference equal to 1. Pick one.
The choice is arbitrary - so long as you are consistent.

Having decided on how to measure angles, we can talk about rotational symmetry.

In general, if the object must be rotated through angle A to map onto itself, then we can define a rotational symmetry value is:
##S=1/A## (circumference = 1)
##S=\pi/A## (diameter = 1, unused)
##S=2\pi/A## (radius =1: this is "radians")
##S=360/A## (using degrees: 1deg = 1/360th of the unit circumference.)

... this is a useful way to define a symmetry number, because it gets bigger the more symmetry you have and, for all common experience, it will always be bigger than one (no fractions). Notice that S, defined this way, will usually be an integer? (The S value ends up being the same as the number of times the object maps onto itself when you rotate it once. i.e. a pentagon would have S=5.)

In a purely abstract way, though, you can ask yourself what happens for non-integer values of S. i.e. what is S=8/3? That's bigger than 1 and not an integer. What is S were irrational?

But that's just pure maths - there was no reason, before QM experiments, to suppose that non-integer symmetries would have any meaning in Nature.

Physics uses Maths as a language for describing Nature.
The formal language involves going through this process of making definitions and proposing theorems.
Maths is a powerful language capable of describing things that do not exist in Nature too.
We use the principles of empirical inquiry to check.
 
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  • #43
Simon Bridge said:
It is determined empirically .
I found a nice link that explains in detail how [itex]\mu[/itex]e is determined as 1.001156 [itex]\mu[/itex]B(=h/4π) in a Penning trap:
http://gabrielse.physics.harvard.edu/gabrielse/overviews/ElectronMagneticMoment/ElectronMagneticMoment.html .
Can you give me a link or explain how Le is concretely determined?
How can you detect and determine mechanical angular momentum at distance, without manipulating a body?
 
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  • #44
That is pretty much the definitive experiment: how much more "concrete" do you need?
 
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  • #45
Simon Bridge said:
That is pretty much the definitive experiment: how much more "concrete" do you need?
Do you mean that spin angular momentum S (Le) and electron magnetic moment [itex]\mu[/itex]e are the same thing? if they are,
Le is = 1* h/2*2π (= [itex]\hbar/2[/itex]), whereas [itex]\mu[/itex]e is 1.001156 * h/2*2 π, which value is right?
 
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  • #46
We've been over this before.
 
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  • #47
Simon Bridge said:
We've been over this before.
I'm lost, in which post(s)?
Can we determine concretely the magnetic moment of a bigger object?
Suppose we have a coil where current is flowing, we have a formula to find the value of B and [itex]\mu[/itex], but is it possible to verify the real value of [itex]\mu[/itex]? what apparatus do we need? a magnetic field of any strength would do or we need a critical value? any direction will do? do we need more than a measurement?
Thanks again for your patience, Simon
 
  • #48
If you have a charge with an angular momentum you must also have a magnetic moment.
They go together.

The other demonstration for angular momentum is a torque experiment - where a spin-polarized beam is incident on a target, the target starts to rotate.

You seem to be going in circles now.
I think you need to have more time to go through these materials.
Intrinsic angular momentum is an established property in physics.
 
  • #49
Simon Bridge said:
You seem to be going in circles now..
Probably I give this impression to you, but I need a couple of notions, before I can read further, I cannot make a synthesis of what I learned so far.Of course I know that a rotating body has L and it has charge it must have a [itex]\mu[/itex], too
I'd appreciate if you could answer my previous question (is this the usual method? :http://www.serviciencia.es/not-apli/NAS01-i.pdf)
bobie said:
Suppose we have a coil where current is flowing,... the real value of [itex]\mu[/itex]?
What I do not understand is the following:
suppose we make that coil spin around the axis of [itex]\mu[/itex], then that coil will have a magnetic moment [itex]\mu[/itex] = k * [itex]\mu[/itex]B and a mechanichal angular momentum L (=mvr) = j * [itex]\hbar[/itex], just like an electron in a 1H atom, am I right so far?

Now, if we measure [itex]\mu[/itex] when the coil is rotating, I assume we get a different value of [itex]\mu[/itex], surely greater, since the applied field must win the resistance to torque also offered by L.
- is that right? naively I assume that, now, the value of [itex]\mu[/itex] must be k+j, or (for some obscure reason) k*j ?

I'd appreciate very much if you could tell me if anything is wrong there. That would save me a lot of more stupid or circular questions. If my assumptions are right, it will be clear to you the fact that I do not understand why:
- if intrinsic angular momentum of the e on the z-axis is [itex]\hbar[/itex]
- and [itex]\mu[/itex] is 1.001156[itex]\hbar[/itex]
when we put a 1H atom in a Stern-Gerlach machine or a single electron in a Penning trap we measure in the first case only L and in the second only [itex]\mu[/itex] (ì 1.1156 L)
Why not always both, and why angular momentum in Stern-Gerlach?
Do you follow me, Simon? probably I should start a new thread on this.

Thanks for your patience!
 
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<H2>What is angular momentum and how is it related to magnetic momentum?</H2><p>Angular momentum is a measure of an object's rotational motion, while magnetic momentum is a measure of an object's magnetic field strength. These two concepts are related through the interaction of a magnetic field and a rotating object, which can produce a torque and change the object's angular momentum.</p><H2>How is angular momentum conserved in magnetic fields?</H2><p>According to the law of conservation of angular momentum, the total angular momentum of a system remains constant unless acted upon by an external torque. In magnetic fields, the angular momentum of a charged particle is conserved as it moves in a circular path due to the interaction between its magnetic moment and the magnetic field.</p><H2>What is the difference between orbital angular momentum and spin angular momentum?</H2><p>Orbital angular momentum is the rotational motion of an object around an external axis, while spin angular momentum is the intrinsic angular momentum of a particle. In other words, orbital angular momentum is associated with the motion of an object, while spin angular momentum is a property of particles themselves.</p><H2>How is magnetic moment related to the direction of angular momentum?</H2><p>The direction of the magnetic moment is always perpendicular to the direction of the angular momentum. This means that the magnetic moment and angular momentum are always at right angles to each other.</p><H2>How do magnetic fields affect the precession of angular momentum?</H2><p>The precession of angular momentum is the gradual change in the direction of the axis of rotation of an object. In the presence of a magnetic field, the precession of angular momentum can be affected due to the torque produced by the interaction between the magnetic field and the object's magnetic moment.</p>

What is angular momentum and how is it related to magnetic momentum?

Angular momentum is a measure of an object's rotational motion, while magnetic momentum is a measure of an object's magnetic field strength. These two concepts are related through the interaction of a magnetic field and a rotating object, which can produce a torque and change the object's angular momentum.

How is angular momentum conserved in magnetic fields?

According to the law of conservation of angular momentum, the total angular momentum of a system remains constant unless acted upon by an external torque. In magnetic fields, the angular momentum of a charged particle is conserved as it moves in a circular path due to the interaction between its magnetic moment and the magnetic field.

What is the difference between orbital angular momentum and spin angular momentum?

Orbital angular momentum is the rotational motion of an object around an external axis, while spin angular momentum is the intrinsic angular momentum of a particle. In other words, orbital angular momentum is associated with the motion of an object, while spin angular momentum is a property of particles themselves.

How is magnetic moment related to the direction of angular momentum?

The direction of the magnetic moment is always perpendicular to the direction of the angular momentum. This means that the magnetic moment and angular momentum are always at right angles to each other.

How do magnetic fields affect the precession of angular momentum?

The precession of angular momentum is the gradual change in the direction of the axis of rotation of an object. In the presence of a magnetic field, the precession of angular momentum can be affected due to the torque produced by the interaction between the magnetic field and the object's magnetic moment.

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