The electric potential difference A V, also called voltage, is expressed in terms of the electric field as follows AV = Edr where, a is the initial position and b is the final position. If an electric field in a region in space is defined as E= - Br2 where Bis just a constant without an arbitrary value. What is the electric potential difference from position 0 to R? 1 AV = BR AV AV = Br 2 O AV = - BR³ Ο Δν-- (1-β)αR3

The electric potential difference A V, also called voltage, is expressed in terms of the electric field as follows AV = Edr where, a is the initial position and b is the final position. If an electric field in a region in space is defined as E= - Br2 where Bis just a constant without an arbitrary value. What is the electric potential difference from position 0 to R? 1 AV = BR AV AV = Br 2 O AV = - BR³ Ο Δν-- (1-β)αR3

University Physics Volume 2

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Chapter8: Capacitance

Section: Chapter Questions

Problem 53P: A parallel-plate capacitor has charge of magnitude 9.00F on each plate and capacitance 3.00F when...

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Question

The electric potential difference AV, also called voltage, is expressed in terms of the electric field as follows
AV = -
Edr
a
where, a is the initial position and b is the final position.
If an electric field in a region in space is defined as
E= - Br2
where B is just a constant without an arbitrary value. What is the electric potential difference from position 0 to R?
1
AV =
- BR
1
AV =
2
AV =
Br
O AV = - BR³
O AV = -(1- B)aR³

1
ΔV =
- BR3
1
ΔV= Br3
2
Δν
O ΔV= -BR3
O ΔV= - (1-B)aR3
1
ㅇ D
ΔV =
ΔV =
BR?
AV = -(1- BaR?
O ΔV= (1-BR2)aR
1
ΔV =
BR3
3

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