Difference between revisions of "Electrostatic pinwheel/Ionic drive"
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Back to [[5B - Electric fields and potentials]]<br> | Back to [[5B - Electric fields and potentials]]<br> | ||
− | PIRA index: 5B30. | + | PIRA index: 5B30.50 |
==Description== | ==Description== | ||
The electric field is stronger around edges. When the field is strong enough charges will escape carrying momentum. Those edges can be aligned in way that the reaction to escaping charges will give the charged object angular momentum. The electrostatic pinwheel demonstrate this effect. | The electric field is stronger around edges. When the field is strong enough charges will escape carrying momentum. Those edges can be aligned in way that the reaction to escaping charges will give the charged object angular momentum. The electrostatic pinwheel demonstrate this effect. | ||
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File:5B30 50 ElectroPinwheel02.JPG | File:5B30 50 ElectroPinwheel02.JPG | ||
</gallery> | </gallery> | ||
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+ | {{#widget:YouTube|id=ker4c1VklBU}} |
Latest revision as of 12:02, 4 March 2021
Back to 5B - Electric fields and potentials
PIRA index: 5B30.50
Description
The electric field is stronger around edges. When the field is strong enough charges will escape carrying momentum. Those edges can be aligned in way that the reaction to escaping charges will give the charged object angular momentum. The electrostatic pinwheel demonstrate this effect.
Equipment
- Metalic arrow with a needle tangential to the radius on each end.
- Pinwheel stand
- Van de Graaff generator
Instructions
- Put the pinwheel stand on the top of ball of the Van de Graaff generator.
- Turn the generator on.
Keywords
Images & Movies