Difference between revisions of "The Electric Field"
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= Textbook = | |||
[https://openstax.org/books/university-physics-volume-2/pages/5-4-electric-field University Physics Volume 2: Chapter 5.4] | |||
= Electric Fields Videos = | |||
= Theory = | |||
== Electric Field == | |||
The electric field acts as a shortcut for calculating the electric force <math> \vec{F} </math> on a test charge <math> q </math>, similar to how the gravitational field <math> g </math> simplifies calculations for gravitational force. Instead of recalculating the force based on Coulomb's Law (and adding the forces of multiple source charges), we can use the electric field, where: | |||
<math> \vec{F} = q_t \cdot \vec{E} </math> | |||
In the same way that <math> \vec{g} </math> gives the gravitational force per kilogram, <math> \vec{E} </math> gives the electric force per coulomb. | |||
=== The Electric Field of a Charged Particle at rest (Point Charge) === | |||
The electric field <math> \vec{E} </math> caused by a point (source) charge <math> Q_s </math> at a distance <math> r </math> from the position is given by: | |||
<math> \vec{E} = k_e \frac{Q_s}{r^2} \hat{r} </math> | |||
where: | |||
* <math> k_e </math> is the electrostatic constant, approximately <math> 8.99 \times 10^9 \, \text{N m}^2/\text{C}^2 </math>. | |||
* <math> Q_s </math> is the point charge creating the electric field (the source charge). | |||
* <math> r </math> is the distance from the charge to the point where the field is being calculated. | |||
* <math> \hat{r} </math> is a unit vector pointing from the charge to the point of interest. | |||
Note that combined with <math> \vec{F} = q_t \cdot \vec{E} </math>, this simply gives you Coulomb's Law. | |||
<youtube>qMnQQudvaE4</youtube> | |||
<youtube>pB-Fjrs1m94</youtube> | |||
<br class="clear"/> | |||
== Electric Field Lines == | |||
'''Electric field lines''' visually represent the direction and strength of an electric field around charges. They point in the direction the electric force would have on a positive test charge. | |||
* Direction: Field lines point '''away''' from positive charges and '''toward''' negative charges. | |||
* Density: The closer the lines, the stronger the electric field in that area. | |||
=== Rules for Drawing Electric Field Lines === | |||
* Lines start or end on charges, with more lines indicating a larger charge magnitude. | |||
* Field lines never cross. | |||
* They form continuous, smooth curves. | |||
<youtube>pbrI1JEBAQU</youtube> | |||
<br class="clear"/> | |||
== Typical Problems with the Electric Field == | |||
<youtube>8GzJOKjp_jA</youtube> | |||
<br class="clear"/> | |||
== Other Videos == | |||
[https://youtu.be/WqvImbn9GG4 MIT Physics Demo -- Faraday's Cage]<br> | |||
<youtube>M1XHjl_6HtM</youtube><br> | |||
<youtube>Zi4kXgDBFhw</youtube><br> | |||
<br class="clear"/> | |||
= Simulations = | |||
*[https://phet.colorado.edu/en/simulations/efield PhET Simulation: Electric Field of Dreams] <br> | |||
*[https://phet.colorado.edu/en/simulations/charges-and-fields PhET Simulation: Charges and Fields] <br> | |||
*[https://phet.colorado.edu/en/simulations/electric-hockey PhET Simulation: Electric Field Hockey] <br> | |||
*[https://phet.colorado.edu/en/simulations/radio-waves PhET Simulation: Radio Waves & Electromagnetic Fields] <br> | |||
*[https://phet.colorado.edu/en/simulations/microwaves PhET Simulation: Microwaves] <br> | |||
= Other Links = | |||
[https://iwant2study.org/lookangejss/05electricitynmagnetism_11efield/ejss_model_electricfieldwee/electricfieldwee_Simulation.xhtml Electric Field vectors]<br> | [https://iwant2study.org/lookangejss/05electricitynmagnetism_11efield/ejss_model_electricfieldwee/electricfieldwee_Simulation.xhtml Electric Field vectors]<br> | ||
[http://hsilomedus.me/wp-content/uploads/d3electricField/electricField.html The Electric Field ] | [http://hsilomedus.me/wp-content/uploads/d3electricField/electricField.html The Electric Field ] | ||
[https://www.falstad.com/vector3de/ The Electric Field-3D] | [https://www.falstad.com/vector3de/ The Electric Field-3D] | ||
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[http://ffden-2.phys.uaf.edu/212_fall2003.web.dir/kristina_smith/description.html Lightning applet]<br> | [http://ffden-2.phys.uaf.edu/212_fall2003.web.dir/kristina_smith/description.html Lightning applet]<br> | ||
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Back to [[Electricity_and_Magnetism]] | |||
[ | <br class="clear"/> | ||
Next: [[Electric Potential]] | |||
[ | |||
Latest revision as of 15:31, 22 November 2024
Back to Electricity_and_Magnetism
Textbook
University Physics Volume 2: Chapter 5.4
Electric Fields Videos
Theory
Electric Field
The electric field acts as a shortcut for calculating the electric force on a test charge , similar to how the gravitational field simplifies calculations for gravitational force. Instead of recalculating the force based on Coulomb's Law (and adding the forces of multiple source charges), we can use the electric field, where:
In the same way that gives the gravitational force per kilogram, gives the electric force per coulomb.
The Electric Field of a Charged Particle at rest (Point Charge)
The electric field caused by a point (source) charge at a distance from the position is given by:
where:
- is the electrostatic constant, approximately .
- is the point charge creating the electric field (the source charge).
- is the distance from the charge to the point where the field is being calculated.
- is a unit vector pointing from the charge to the point of interest.
Note that combined with , this simply gives you Coulomb's Law.
Electric Field Lines
Electric field lines visually represent the direction and strength of an electric field around charges. They point in the direction the electric force would have on a positive test charge.
- Direction: Field lines point away from positive charges and toward negative charges.
- Density: The closer the lines, the stronger the electric field in that area.
Rules for Drawing Electric Field Lines
- Lines start or end on charges, with more lines indicating a larger charge magnitude.
- Field lines never cross.
- They form continuous, smooth curves.
Typical Problems with the Electric Field
Other Videos
MIT Physics Demo -- Faraday's Cage
Simulations
- PhET Simulation: Electric Field of Dreams
- PhET Simulation: Charges and Fields
- PhET Simulation: Electric Field Hockey
- PhET Simulation: Radio Waves & Electromagnetic Fields
- PhET Simulation: Microwaves
Other Links
Back to Electricity_and_Magnetism
Next: Electric Potential