qpt Shown in the figure is a point charge that has been placed in the center of a spherical conducting shell with an inner radius of 0.6 meters. The outer surface of the spherical conducting shell has been connected to ground. A "ground" is just a place to gain electrons from, or lose electrons too. After coming to equilibrium, where charge stops moving in the system, the surface charge density on the inner shell is 20 nC/m2, calculate the net charge of the point charge in nanocoulombs.

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Question 8
9pt
Shown in the figure is a point charge that has been placed in the center of a spherical
conducting shell with an inner radius of 0.6 meters. The outer surface of the
spherical conducting shell has been connected to ground. A "ground" is just a place
to gain electrons from, or lose electrons too. After coming to equilibrium, where
charge stops moving in the system, the surface charge density on the inner shell is
20 nC/m2, calculate the I charge of the point charge in nanocoulombs.
Enter you answer in units of nC rounding your final answer to two decimal places. If
Transcribed Image Text:Question 8 9pt Shown in the figure is a point charge that has been placed in the center of a spherical conducting shell with an inner radius of 0.6 meters. The outer surface of the spherical conducting shell has been connected to ground. A "ground" is just a place to gain electrons from, or lose electrons too. After coming to equilibrium, where charge stops moving in the system, the surface charge density on the inner shell is 20 nC/m2, calculate the I charge of the point charge in nanocoulombs. Enter you answer in units of nC rounding your final answer to two decimal places. If
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