Three particles lie on the x-axis: particle 1, with a charge of 2.00 μC is at 1.00 cm, particle 2, with a charge of -2.00 μC, is atX = 2.00 cm, and particle 3, with a charge of -2.00 µC, is at x = 3.00 cm. The potential energy of this arrangement, relativeto the potential energy for infinite separation, is1.80 J8.99 JO -1.80 JO -2.48 JO 2.48 J

Given, Charge q1 = 2.00 μC at x = 1.00 cmq2 = -2.00 μC at x = 2.00 cmq3 = -2.00 μC at x = 3.00 cm

Three particles lie on the x-axis: particle 1, with a charge of 2.00 μC is at 1.00 cm, particle 2, with a charge of -2.00 μC, is at x = 2.00 cm, and particle 3, with a charge of -2.00 μC, is at x = 3.00 cm. The potential energy of this arrangement, relative to the potential energy for infinite separation, is O 1.80 J O 8.99 J O -1.80 J O -2.48 J O 2.48 J

Three particles lie on the x-axis: particle 1, with a charge of 2.00 μC is at 1.00 cm, particle 2, with a charge of -2.00 μC, is at x = 2.00 cm, and particle 3, with a charge of -2.00 μC, is at x = 3.00 cm. The potential energy of this arrangement, relative to the potential energy for infinite separation, is O 1.80 J O 8.99 J O -1.80 J O -2.48 J O 2.48 J

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter26: Electric Potential

Section: Chapter Questions

Problem 14PQ: Four charged particles are at rest at the corners of a square (Fig. P26.14). The net charges are q1...

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