Conductors: Difference between revisions
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*Lossy Materials: σ > 0 | *Lossy Materials: σ > 0 | ||
*Conductors: σ >> 0 | *Conductors: σ >> 0 | ||
Below is a breakdown of how conductivity is calculated. This could be considered a formula for conductivity, but it would be more accurate to think of it as a definition. | |||
[[File:Electric conductivity equation.jpg|400 px]] | |||
Conductivity can also be explained as the inverse of resistivity. σ = 1/ρ where ρ is resistivity. | |||
===A Computational Model=== | ===A Computational Model=== | ||
Revision as of 19:23, 20 March 2020
Conducting material allows electric current to travel with little resistance throughout. This is related to the structure of the atoms of the conductor. In this section, we will look at what a conductor is, why it is this way, and the applications.
The Main Idea
Conductors are defined a material that allows charged particles to move easily throughout. Charges placed on the surface of a conductor will not simply sit there or only spread over the surface, it will immediately spread evenly throughout the conductor given there are no interfering forces. If the conductor is in an electric field, for example, it will cause the (negative) charges to move in the opposite direction of the field.
how conductors work atomically Electric current flows by the net movement of electric charge. This can be by electrons, ions, or other charged particles.
Conductors allow for easy movement of charged particles because of the structure of the atoms. The outermost electrons in the conductors are only loosely bound and allow for more interaction with other particles. The idea that electrons move completely free from their atom in the conductor is not entirely accurate, but it will be a perfectly working approximation for our level of analysis.
There are some factors that can change the conductance of a conductor. Shape and size, for example, affect the conductance of an object. A thicker(larger cross sectional area A in the diagram) piece will be a better conductor than a thinner piece of the same material and other dimensions in the same way that a thicker piece of wire allows for greater current flow. The larger cross sectional area allows for more flow of charge carriers. A shorter conductor will also conduct better since it has less resistance than a longer piece. Conductance itself can also change conductivity. In actively conducting electric current, the conductor heats up. This is secretly the third factor affecting conductance, temperature. Changes in temperature can cause the same object to have a different conductance under otherwise identical conditions. The most well known example of this is glass. Glass is more of an insulator at typical to cold temperatures, but becomes a good conductor at higher temperatures. Generally, metals are better conductors at cooler temperatures. This is because an increase in temperature is an increase in energy, specifically for electrons.
A Mathematical Model
Ohm's Law of J = σE can be used to model the relationship of conductivity to electric current density where J is electric current density, σ is conductivity of the material, and E is electric field. This is a generalized form of the well known V = IR.
σ is greater for better conductors like metals and saltwater. For "perfect" conductors, σ approaches infinity. E is therefore zero since the current density J is cannot approach infinity.
Materials are generally divided into three categories based on σ:
- Lossless Materials: σ = 0
- Lossy Materials: σ > 0
- Conductors: σ >> 0
Below is a breakdown of how conductivity is calculated. This could be considered a formula for conductivity, but it would be more accurate to think of it as a definition.
Conductivity can also be explained as the inverse of resistivity. σ = 1/ρ where ρ is resistivity.
A Computational Model
How do we visualize or predict using this topic. Consider embedding some vpython code here Teach hands-on with GlowScript
https://phet.colorado.edu/en/simulation/semiconductor
Examples
Simple
question
solution
Middling
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solution
Difficult
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solution
Connectedness
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- How is it connected to your major?
- Is there an interesting industrial application?
History
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See also
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Further reading
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External links
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References
https://en.wikipedia.org/wiki/Electrical_conductor
https://www.thoughtco.com/examples-of-electrical-conductors-and-insulators-608315
https://www.rpi.edu/dept/phys/ScIT/InformationProcessing/semicond/sc_glossary/scglossary.htm