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24. Electric Force & Field; Gauss' Law

Electric Fields in Conductors

Physics

24. Electric Force & Field; Gauss' Law

Electric Fields in Conductors

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2:40 minutes

Problem 39

Textbook Question

Figure 24.32b showed a conducting box inside a parallel-plate capacitor. The electric field inside the box is $E right arrow equals 0 right arrow$ . Suppose the surface charge on the exterior of the box could be frozen. Draw a picture of the electric field inside the box after the box, with its frozen charge, is removed from the capacitor. Hint: Superposition.

Verified step by step guidance

Understand the problem: The conducting box inside the parallel-plate capacitor initially has an electric field inside it of $ \mathbf{E} = 0 $. This is because the conducting box redistributes its charges to cancel the external electric field inside it. The problem asks us to analyze the electric field inside the box after it is removed from the capacitor, with its surface charge distribution frozen.

Recall the concept of superposition: The principle of superposition states that the net electric field at any point is the vector sum of the electric fields due to all charges present. In this case, the frozen surface charge on the box will now act as the source of the electric field.

Visualize the frozen charge distribution: When the box was inside the capacitor, the charges on its surface redistributed to cancel the external electric field inside the box. This means the surface charge distribution is non-uniform, with positive charges on one side and negative charges on the opposite side, corresponding to the direction of the original external field.

Determine the electric field inside the box: After the box is removed from the capacitor, the frozen surface charges will create their own electric field. Inside the box, the electric field will no longer be zero because the external field from the capacitor is no longer present to cancel the field due to the surface charges. The resulting electric field inside the box will depend on the frozen charge distribution and can be calculated using Gauss's law or Coulomb's law.

Draw the electric field: To represent the electric field inside the box, draw field lines originating from the positive charges on the surface and terminating at the negative charges. The field lines inside the box will point from the positively charged region to the negatively charged region, reflecting the frozen charge distribution.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Electric Field

An electric field is a vector field that represents the force exerted by an electric charge on other charges in its vicinity. It is defined as the force per unit charge and is directed away from positive charges and toward negative charges. In the context of capacitors, the electric field between the plates is uniform and plays a crucial role in determining the behavior of charges within conductive materials.

Superposition Principle

The superposition principle states that the total electric field created by multiple charges is the vector sum of the electric fields produced by each charge independently. This principle allows us to analyze complex charge distributions by considering the contributions from individual charges separately, making it essential for understanding the behavior of electric fields in various configurations, such as when a conducting box is involved.

Conductors in Electrostatics

In electrostatics, conductors are materials that allow free movement of electric charges. When placed in an electric field, charges within a conductor redistribute themselves until the electric field inside the conductor is zero. This property is crucial for understanding how the conducting box affects the electric field in the capacitor and how the removal of the box will alter the field configuration in the surrounding space.

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A charged paint is spread in a very thin uniform layer over the surface of a plastic sphere of diameter $12.0$ cm, giving it a charge of $negative 49.0$ $μ$ C. Find the electric field just inside the paint layer.

Textbook Question

An infinitely wide, horizontal metal plate lies above a horizontal infinite sheet of charge with surface charge density 800 nC/m². The bottom surface of the plate has surface charge density -100 nC/m². What is the surface charge density on the top surface of the plate?

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Textbook Question

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A charged paint is spread in a very thin uniform layer over the surface of a plastic sphere of diameter $12.0$ cm, giving it a charge of $−49.0$ $μ$ C. Find the electric field just outside the paint layer;

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