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184_notes:changing_e [2020/08/24 17:51] – dmcpadden | 184_notes:changing_e [2021/07/22 13:47] (current) – schram45 |
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{{youtube>QgIz4GQgy-E}} | {{youtube>QgIz4GQgy-E}} |
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==== Extra Term to Ampere's Law ==== | ===== Extra Term to Ampere's Law ===== |
From Faraday's Law, we learned that a changing magnetic field creates a curly electric field. As a similar parallel, we are now saying that a changing electric field (with time) creates a curly magnetic field. Conveniently, we already have an equation that describes a curly magnetic field: Ampere's Law. | From Faraday's Law, we learned that a changing magnetic field creates a curly electric field. As a similar parallel, we are now saying that a changing electric field (with time) creates a curly magnetic field. Conveniently, we already have an equation that describes a curly magnetic field: Ampere's Law. |
$$\int \vec{B} \bullet d\vec{l} = \mu_0 I_{enc}$$ | $$\int \vec{B} \bullet d\vec{l} = \mu_0 I_{enc}$$ |
This term that we added to Ampere's Law functions in much the same way as Faraday's law. If we can calculate the changing electric flux through a loop, then we can use that to find the magnetic field that curls around that loop. In the example below, we use a charging capacitor to illustrate how this can done; however, for the purposes of this class, we will primarily rely on this idea conceptually (rather than asking you to calculate the magnetic field from a changing electric flux). | This term that we added to Ampere's Law functions in much the same way as Faraday's law. If we can calculate the changing electric flux through a loop, then we can use that to find the magnetic field that curls around that loop. In the example below, we use a charging capacitor to illustrate how this can done; however, for the purposes of this class, we will primarily rely on this idea conceptually (rather than asking you to calculate the magnetic field from a changing electric flux). |
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==== Why this Matters ==== | ===== Why this Matters ===== |
With this final piece of the puzzle, we can actually say something really important about how electric and magnetic fields work. If we //__assume that there are no current-carrying wires nearby__//, then we have a set of two equations that say that: | With this final piece of the puzzle, we can actually say something really important about how electric and magnetic fields work. If we //__assume that there are no current-carrying wires nearby__//, then we have a set of two equations that say that: |
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==== Examples ==== | ==== Examples ==== |
[[:184_notes:examples:Week14_b_field_capacitor|Magnetic Field from a Charging Capacitor]] | * [[:184_notes:examples:Week14_b_field_capacitor|Challenge: Magnetic Field from a Charging Capacitor]] |
| * Video Example: Magnetic Field from a Charging Capacitor |
| {{youtube>mWH9WHKFyTE?large}} |