Three point charges, q₁ = +52 μC, q2 = -52 μC, and93 = 85 μC, are fixed in place at the corners of a rectanglethat is 2.5-cm tall and 5-cm wide as shown in the figure.1. Electric Potential EnergyCalculate the electric potential energy of the system of charges.UE =Submit2. Electric PotentialCalculate the electric potential at point P.Vp =Submit3. And Now a DodoMV2.5 cmThe last surviving dodo bird had been hiding out on a far-away island with only a 43-μC point charge for company.Hoping to trade the charge for a mate, the dodo carried the charge from the island and dropped it at point, P.J5.0 cm(a) How much work did the electric field of the three charges do on the dodo's point charge?WE=(b) How much did the electric potential energy change when the dodo put his charge at point P?AUE=(c) What is the electric potential energy of the system of charges now?UE=J

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Three point charges, q₁ = +52 μC, q2 = -52 μC, and 93 = 85 μC, are fixed in place at the corners of a rectangle that is 2.5-cm tall and 5-cm wide as shown in the figure. 1. Electric Potential Energy Calculate the electric potential energy of the system of charges. U₁ = J Submit 2. Electric Potential Calculate the electric potential at point P. Vp = MV

Three point charges, q₁ = +52 μC, q2 = -52 μC, and 93 = 85 μC, are fixed in place at the corners of a rectangle that is 2.5-cm tall and 5-cm wide as shown in the figure. 1. Electric Potential Energy Calculate the electric potential energy of the system of charges. U₁ = J Submit 2. Electric Potential Calculate the electric potential at point P. Vp = MV

University Physics Volume 2

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Chapter7: Electric Potential

Section: Chapter Questions

Problem 64P: The surface charge density on a long straight metallic pipe is . What is the electric potential...

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Electric Charges and Fields

One of the fundamental properties is the electromagnetic property. Charge cannot be destroyed by any process and this contributes formally to the law of charge conservation.

Question

Three point charges, q₁ = +52 μC, q2 = -52 μC, and
93 = 85 μC, are fixed in place at the corners of a rectangle
that is 2.5-cm tall and 5-cm wide as shown in the figure.
1. Electric Potential Energy
Calculate the electric potential energy of the system of charges.
UE =
Submit
2. Electric Potential
Calculate the electric potential at point P.
Vp =
Submit
3. And Now a Dodo
MV
2.5 cm
The last surviving dodo bird had been hiding out on a far-away island with only a 43-μC point charge for company.
Hoping to trade the charge for a mate, the dodo carried the charge from the island and dropped it at point, P.
J
5.0 cm
(a) How much work did the electric field of the three charges do on the dodo's point charge?
WE=
(b) How much did the electric potential energy change when the dodo put his charge at point P?
AUE=
(c) What is the electric potential energy of the system of charges now?
UE=
J

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