× 10-4C. Assume that Coulomb’s constant, (k) is equal to 9.0×109 N × m2/c2 a) Determine the total electric potential energy for the charge distribution. b) Determine the total electric potential at point Z.

× 10-4C. Assume that Coulomb’s constant, (k) is equal to 9.0×109 N × m2/c2 a) Determine the total electric potential energy for the charge distribution. b) Determine the total electric potential at point Z.

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Question

1. Examine the charge distribution shown. Sphere 1 has a charge of +3.0 × 10^-4C; sphere 2 has a charge of –3.0 × 10^-4C; and sphere 3 has a charge of +3.0 × 10^-4C. Assume that Coulomb’s constant, (k) is equal to 9.0×10⁹ N × m²/c²

a) Determine the total electric potential energy for the charge distribution.

b) Determine the total electric potential at point Z.

4.24 m
4.24 m.
3.00 m
3.00 m
3.00 m
q,
92
93

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