Electron spin, why do the pairs have to be opposite?

In summary: In fact, it is not. So, there must be some other mechanism at work here.In summary, the experiment described involves two electrons with opposite spins being observed by two people in different locations. The initial state of the electrons is designed to have a total angular momentum of zero, leading to the conservation of total angular momentum when one electron is observed to have an upward spin, causing the other electron to have a downward spin. This experiment relies on the concept of entanglement and conservation of spin.
  • #1
Sephiroth2088
4
0
In the experiment where there are two electrons, and one is shot out to a person, the experiment depends on the two having opposite spins, one up one down, though which has which is not determined until observation.

So person 1 looks at theirs and sees it's an upward spin. This collapses person 2s to downward imediantly. So even if the other person was 2 billion lightyears away at that time, it would still effect instantly. This experiment makes sense, aside from one thing.

How do they know that one is up spin, and one is down spin to begin with?

I think I may have learned in chemistry that on the same valance level, electrons must have opposite spins or something, is that it or am I completely off?
 
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  • #2
Sephiroth2088 said:
In the experiment where there are two electrons, and one is shot out to a person, the experiment depends on the two having opposite spins, one up one down, though which has which is not determined until observation.

So person 1 looks at theirs and sees it's an upward spin. This collapses person 2s to downward imediantly. So even if the other person was 2 billion lightyears away at that time, it would still effect instantly. This experiment makes sense, aside from one thing.

How do they know that one is up spin, and one is down spin to begin with?

I think I may have learned in chemistry that on the same valance level, electrons must have opposite spins or something, is that it or am I completely off?

No they do not need, in general, to have opposite spins.

You are describing an entanglement experiment. Although there seems to
be an element of randomness in the "collapse of the wavefunction", it is
not that random. The conservation laws must be all obeyed and in this
case it's the conservation of spin.

Another experiment would be where both particles have the same spin, but
of unknown direction. So if one is up the other must be up as well, and visa
versa, if one is down the other must be down as well.


Regards, Hans
 
  • #3
Sephiroth2088 said:
How do they know that one is up spin, and one is down spin to begin with?

Because the experimental setup is constructed specifically so that the initial state that produces the two electrons (or whatever kind of particle is being used) has a total angular momentum of zero. Therefore, by conservation of total angular momentum, the sum of the particles' angular momenta must also be zero.
 
  • #4
jtbell said:
Therefore, by conservation of total angular momentum, the sum of the particles' angular momenta must also be zero.
But still, just to be picky, this does not necessarily imply that the total spin of the two electron system is zero.
 

1. What is electron spin and why is it important?

Electron spin is a fundamental property of electrons, and it refers to the rotation of an electron on its axis. It is important because it allows us to understand and predict the behavior of electrons in different chemical and physical environments.

2. How is electron spin related to magnetism?

Electron spin is closely related to magnetism because the spinning motion of electrons creates a magnetic field. In materials with unpaired electrons, these magnetic fields can align and produce a net magnetic moment, resulting in magnetism.

3. Why do electrons have to pair up with opposite spins?

This is due to the Pauli exclusion principle, which states that no two electrons in an atom can have the same set of quantum numbers. Since electrons have spin quantum numbers of either +1/2 or -1/2, they must pair up with opposite spins to have different quantum numbers and follow the principle.

4. Can electron spin be changed or manipulated?

Yes, electron spin can be changed or manipulated through various techniques such as applying a magnetic field or using spin-polarized current. This is a promising area of research for the development of new technologies such as spintronics.

5. How does electron spin influence chemical bonding?

Electron spin plays a crucial role in chemical bonding as it determines the electronic structure and stability of atoms and molecules. In covalent bonding, for example, electrons with opposite spins are paired up to form a bond between atoms, resulting in a more stable configuration.

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