Understanding the Cooper pair in real space

In summary, the Cooper pair in real space involves two electrons with opposite momentum states, regardless of the pairing symmetry. The net current is a result of long-range coherence and cannot be determined by looking at individual events. In order to have a net current, the center of mass must have a nonzero speed.
  • #1
neuva
1
0
I am trying to understand the pairing mechanism in the Cooper pair in real space. When I googled the image of the Cooper pair, there are two different pictures explaining the pairing. While one describe the second electron moving in the same direction, other describe it as moving along the same direction. Which one is correct? Does this answer depends on the pairing symmetry? s, p, d-wave?

Moreover, if the answer is that two electrons are moving in opposite direction, how can there be a net current? Thank you in advance.
 
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  • #2
neuva said:
I am trying to understand the pairing mechanism in the Cooper pair in real space. When I googled the image of the Cooper pair, there are two different pictures explaining the pairing. While one describe the second electron moving in the same direction, other describe it as moving along the same direction. Which one is correct? Does this answer depends on the pairing symmetry? s, p, d-wave?

Moreover, if the answer is that two electrons are moving in opposite direction, how can there be a net current? Thank you in advance.

The cartoon picture is there to depict that, to preserve the fermion statistics, the 2 electrons that are in close proximity to each other have opposite momentum (k) states. This is true regardlesso of the pairing symmetry.

For the last part, this is more difficult to visualize. You need to know that electrons continue to scatter in and out of these states, i.e. you have no way of tracking which electrons are doing what. All you have in the description is that these Cooper Pair states are occupied. The super current is more of the result of long-range coherence of the condensate.

Also remember that in classical statistics, you can have a purely random scattering events and still have a net drift velocity in a particular direction of the whole ensemble. So looking at just one event or one pair, as in this case, will not give you the correct picture on the current transport.

Zz.
 
  • #3
neuva;4446728 Moreover said:
They only move in opposite directions if the net current is zero. If the current is nonvanishing, the center of mass has a nonzero speed and the electrons only move in different directions with respect to the center of mass frame.
 

1. What is a Cooper pair?

A Cooper pair is a pair of electrons that are attracted to each other due to the interaction with the lattice of a superconductor. This pairing allows for the electrons to move through the material without any resistance, creating superconductivity.

2. How do Cooper pairs form in real space?

Cooper pairs form when two electrons with opposite spins and momenta interact with the lattice of a superconductor. This interaction creates an attractive force between the electrons, causing them to form a pair and move together through the material.

3. What is the significance of understanding Cooper pairs in real space?

Understanding Cooper pairs in real space is crucial for understanding the mechanism of superconductivity and developing new superconducting materials. It also helps in the development of technologies that rely on superconductors, such as MRI machines and particle accelerators.

4. Can Cooper pairs exist outside of superconductors?

Yes, Cooper pairs can exist in other types of materials, such as semiconductors or metals, but they do not exhibit the same properties as in superconductors. In these materials, the Cooper pairs are not able to move without resistance, and therefore do not create superconductivity.

5. How is the understanding of Cooper pairs in real space related to quantum mechanics?

The formation and behavior of Cooper pairs in real space is governed by quantum mechanics. This is because the pairing occurs due to the exchange of phonons, which are quantum-mechanical vibrations in the lattice of a material. Additionally, the movement of Cooper pairs through a superconductor can only be explained by quantum mechanics.

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