How do electricity and superconductors work?

In summary, electricity is a mysterious entity that has been plaguing my mind since last year. I don't understand why electrons move the way they do, nor what is the driving force to make them do so. However, the water pipe analogy explains voltage in a way that is easy to understand.
  • #1
h1010134
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Electricity has been a mysterious entity plaguing my mind since last year when I learned about it in class. I am unable to understand why electrons move the way they do when a circuit is formed, nor what is the driving force to make them do so (which is voltage difference, and I don't understand that either). Electron flow has been analogued as a water pump system in class, and that does work in allowing me to visualise resistance etc, as how water in the analogue comes into contact with the walls of the pipe. However, the analogy fails to show me what is voltage, as the water pump does not magically work on it's own - it requires electricity. So, I'd like to be clearer on how electricity works, preferably explained with a visual image.

As to superconductors, I already have an image of it, gained from some source on the web. The image is this - Normal conductors are shown as a messy train station, with electrons analogued as people, moving to the trains in a disorderly fashion, thereby bumping into other things (nuclei) and other people (hence the resistance). In superconductors, these people pair up and move to trains orderly, thereby not hitting anything. What I'd like to know is why electrons pair up in superconductors, especially since they should repel each other due to their like charges.

Any response would be appreciated. Thanks!
 
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  • #2
Voltage difference => electric field => force on electrons

In the water pipe analogy, voltage corresponds to pressure or height of the water level.

as the water pump does not magically work on it's own - it requires electricity.
And electric power supplies do not work on their own either, they need other forms of energy (chemical in batteries, mechanical in generators, light in photovoltaics, ...).

What I'd like to know is why electrons pair up in superconductors, especially since they should repel each other due to their like charges.
Their interaction with the atomic lattice and its vibrations gives a (small) attractive force. For low-temperature superconductors, this can be described with the BCS theory. For high-temperature superconductors, it is an open question.
 
  • #3
h1010134 said:
Electricity has been a mysterious entity plaguing my mind since last year when I learned about it in class. I am unable to understand why electrons move the way they do when a circuit is formed, nor what is the driving force to make them do so (which is voltage difference, and I don't understand that either).

Voltage is a difference in electric potential. Imagine you have a positive charge and a negative charge separated a short distance apart. Since they attract each other they will feel a force that accelerates them towards each other. This is electric potential. The POTENTIAL for work to be done. (Work being the movement of the charges)

Now, if you throw a circuit into an area where electric potential is the same everywhere, you won't get any net movement through the circuit. Your circuit as a whole will just have a slight imbalance in charge between two sides that aligns with the electric field. (AKA negative charge will build up slightly on one side and positive on the opposite) You need a DIFFERENCE in potential to cause current to flow. Imagine you are on a plateau. You have gravitational potential energy, as does your buddy nearby, but you can't use gravity to do any work between you. If however, your buddy stands off the side a little bit and is now lower, he has less potential energy than you, and you now have a DIFFERENCE in potential energy between the two of you. You can use this difference to do work, such as dropping a ball to him. The same applies to a circuit. If you have a DIFFERENCE in electric potential then charges at one point will not have the same force as charges at another point and they will move.

The full technical version can be found at the link below, as electric potential is a measure of the amount of electric potential energy of a particle. From the example above each charge has potential energy since they are attracted to each other.

http://en.wikipedia.org/wiki/Electric_potential_energy


Electron flow has been analogued as a water pump system in class, and that does work in allowing me to visualise resistance etc, as how water in the analogue comes into contact with the walls of the pipe. However, the analogy fails to show me what is voltage, as the water pump does not magically work on it's own - it requires electricity. So, I'd like to be clearer on how electricity works, preferably explained with a visual image.

It doesn't really matter how the analogy does it, just realize that voltage is pressure from the pump. You could replace the electric pump with a manual one. Either way it's just an analogy, so you won't be able to visualize it completely no matter what is said.

As to superconductors, I already have an image of it, gained from some source on the web. The image is this - Normal conductors are shown as a messy train station, with electrons analogued as people, moving to the trains in a disorderly fashion, thereby bumping into other things (nuclei) and other people (hence the resistance). In superconductors, these people pair up and move to trains orderly, thereby not hitting anything. What I'd like to know is why electrons pair up in superconductors, especially since they should repel each other due to their like charges.

Any response would be appreciated. Thanks!

This is a complicated topic. What happens is that as the electrons move through the lattice, they leave behind a "hole" where they used to be. This hole has a positive charge and attracts another electron to it. At low temperatures two electrons can "pair up" because of this effect. Since they are now paired up, in order for one electron to bump into anything, it must break this bond between itself, the hole, and its paired electron. This requires energy to break the bond. At low temperatures there isn't enough energy to break this bond so the electrons don't "bump" into anything and thus have zero resistance. This is just a basic explanation, and an understanding of Quantum Mechanics is necessary to really grasp this topic.
 
  • #4
Wow QQ that's going to be a lot of reading material ^^ thank you!
 
  • #5


Dear student,

I understand your curiosity about electricity and superconductors. Let me explain these concepts to you in a simple and visual manner.

Firstly, electricity is the flow of electrons through a conductive material, such as a wire. These electrons are negatively charged particles that are constantly moving. In a circuit, when a voltage difference is applied, it creates an electric field that pushes the electrons in one direction, creating a flow of electricity. Think of it like a river flowing downhill due to gravity. The voltage difference is like the slope of the river, and the electrons are like the water molecules moving down the slope.

Now, let's talk about superconductors. Superconductors are materials that have zero electrical resistance when cooled below a certain temperature. This means that the electrons can flow through them without any obstacles, unlike in normal conductors where they collide with atoms and cause resistance. In superconductors, the electrons form pairs called Cooper pairs, which move together in a coordinated manner. This pairing is caused by a phenomenon called electron-phonon interaction, where the vibrations of the atoms in the material attract the electrons and cause them to pair up.

So, to summarize, electricity works by the movement of electrons in a conductive material, and superconductors allow for a smooth flow of electrons by pairing them up through electron-phonon interaction. I hope this visual explanation helps you understand these concepts better. Keep asking questions and exploring the world of science!
 

1. How does electricity flow through a wire?

Electricity flows through a wire due to the movement of electrons. When a voltage is applied to the wire, the electrons are pushed by the electric field and flow in a specific direction. This flow of electrons is what we refer to as electricity.

2. What is the difference between conductors and insulators?

Conductors are materials that allow electricity to flow through them easily, while insulators are materials that do not allow electricity to flow through them. This is due to the difference in the number of free electrons in each material. Conductors have more free electrons, while insulators have fewer.

3. What makes a material a superconductor?

A material is considered a superconductor when it has the ability to conduct electricity with zero resistance at very low temperatures. This is due to the formation of Cooper pairs, which are pairs of electrons that can move through the material without any resistance.

4. How do superconductors work?

Superconductors work by expelling any magnetic fields that try to enter them. This is known as the Meissner effect. When a magnetic field is applied to a superconductor, the electrons in the Cooper pairs align themselves in a way that cancels out the magnetic field, allowing for the flow of electricity with zero resistance.

5. What are the practical applications of superconductors?

Superconductors have a wide range of practical applications, including use in MRI machines, particle accelerators, and high-speed trains. They are also used in the production of highly sensitive sensors and in the development of quantum computers. Superconductors have the potential to revolutionize many industries by providing efficient and cost-effective solutions for electricity transmission and storage.

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