Difference between revisions of "Maxwell's Equations"
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These are the Maxwell's Equations we will be using to solve for regions "I" and "II" in our approximation of the Michelson interferometer. | These are the Maxwell's Equations we will be using to solve for regions "I" and "II" in our approximation of the Michelson interferometer. | ||
| − | Gauss' Law: | + | {|align=center |
| − | + | |Gauss' Law: | |
| − | <math>\boldsymbol{\nabla \cdot E} = 0 </math> | + | |<math>\boldsymbol{\nabla \cdot E} = 0 </math> |
| − | + | |Gauss' Law for Magnetism: | |
| − | Gauss' Law for Magnetism: | + | |<math>\boldsymbol{\nabla \cdot B} = 0</math> |
| − | + | |- | |
| − | <math>\boldsymbol{\nabla \cdot B} = 0</math> | + | |Faradays's Law: |
| − | + | |<math>\boldsymbol{\nabla \times E} + \frac{\partial \boldsymbol{B}}{\partial t}= 0</math> | |
| − | Faradays's Law: | + | |Ampere's Law: |
| − | + | |<math>\boldsymbol{\nabla \times B} - \mu_0\epsilon_0\frac{\partial \boldsymbol{E}}{\partial t}= 0 </math> | |
| − | <math>\boldsymbol{\nabla \times E} + \frac{\partial \boldsymbol{B}}{\partial t}= 0</math> | + | |} |
| − | |||
| − | Ampere's Law: | ||
| − | |||
| − | <math>\boldsymbol{\nabla \times B} - \mu_0\epsilon_0\frac{\partial \boldsymbol{E}}{\partial t}= 0 </math> | ||
== In the presence of charges and dielectric media == | == In the presence of charges and dielectric media == | ||
Revision as of 15:42, 21 March 2007
In Free Space
These are the Maxwell's Equations we will be using to solve for regions "I" and "II" in our approximation of the Michelson interferometer.
| Gauss' Law: | Gauss' Law for Magnetism: | ||
| Faradays's Law: | Ampere's Law: |
In the presence of charges and dielectric media
Need to add possibly derivation of wave equation and definitely Maxwell's equation in presence. Need also to introduce D and H and relate them to E and B.
Gauss' Law:
Gauss' Law for Magnetism:
Faradays's Law:
Ampere's Law:
