A small, rigid object carries positive and negative 5.00 nC charges. It is oriented so that the positive charge has coordinates (-1.20 mm, 1.00 mm) and the negative charge is at the point (1.50 mm, -1.30 mm).(a) Find the electric dipole moment of the object.C•mî +C•mĵ(b) The object is placed in an electric field E =(7.80 x 103 î – 4.90 x 103 ĵ) N/C.Find the torque acting on the object.N• m ---Select--- v(c) Find the potential energy of the object-field system when the object is in this orientation.(d) Assuming the orientation of the object can change, find the difference between the maximum and the minimum potential energies of the system.J

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A small, rigid object carries positive and negative 5.00 nC charges. It is oriented so that the positive charge has coordinates (-1.20 mm, 1.00 mm) and the negative charge is at the point (1.50 mm, -1.30 mm). (a) Find the electric dipole moment of the object. C.mî + C.mj (b) The object is placed in an electric field E = (7.80 x 103 î - 4.90 x 103 j) N/C.Find the torque acting on the object. N.m ---Select-- v (c) Find the potential energy of the object-field system when the object is in this orientation. (d) Assuming the orientation of the object can change, find the difference between the maximum and the minimum potential energies of the system.

A small, rigid object carries positive and negative 5.00 nC charges. It is oriented so that the positive charge has coordinates (-1.20 mm, 1.00 mm) and the negative charge is at the point (1.50 mm, -1.30 mm). (a) Find the electric dipole moment of the object. C.mî + C.mj (b) The object is placed in an electric field E = (7.80 x 103 î - 4.90 x 103 j) N/C.Find the torque acting on the object. N.m ---Select-- v (c) Find the potential energy of the object-field system when the object is in this orientation. (d) Assuming the orientation of the object can change, find the difference between the maximum and the minimum potential energies of the system.

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter24: Electric Fields

Section24.5: Electric Field Of A Continuous Charge Distribution

Problem 24.6CE: a. Figure 24.22A shows a rod of length L and radius R with excess positive charge Q. The excess...

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