Voltage and distance and E Field

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Presentation transcript:

Voltage and distance and E Field Definition: (derive) E = -ΔV Δx E = Electric Field ΔV = Voltage change Δx = distance over which it changes (Why the minus sign) (Why I generally ignore it) E + - Δx Parallel Plates

Example 1: What is the electric field when you have 12 Example 1: What is the electric field when you have 12.0 V across two || plates that are separated by .0150 m? 800. V/m. (show units)

Example 2: Carson Busses needs to suspend a 1. 5 g ( Example 2: Carson Busses needs to suspend a 1.5 g (.0015 kg) pith ball against gravity. (gravity = electric) It has a charge of +12 C, and he is generating the electric field using plates that are 3.5 cm apart. What voltage should he use? Which side (top or bottom) is positive? +Q 43 V, bottom

Voltage, Electric Field, and distance Whiteboards: Voltage, Electric Field, and distance 1 | 2 | 3 | 4 TOC

Lei DerHosen places a voltage of 25 V across two || plates separated by 5.0 cm of distance. What is the electric field generated? E = -ΔV/Δx, ΔV = 25, Δx = .050 m, E = 500 V/m 5.0x102 V/m

Art Zenkraftz measures a 125 V/m electric field between some || plates separated by 3.1 mm. What must be the voltage across them? E = -ΔV/Δx, Δx = 3.1x10-3 m, E = 125 V/m ΔV = 0.3875 V = 0.39 V 0.39 V

Oliver Goodguy needs to generate a 13 V/m electric field using a 1 Oliver Goodguy needs to generate a 13 V/m electric field using a 1.50 V source. What distance should he separate || plates to generate this electric field? E = -ΔV/Δx, ΔV = 1.50 V,, E = 13 V/m Δx = 0.1154 m = 0.12 m = 12 cm 12 cm