Vídeo: Lei de Ampère-Maxwell: Resolução de Problemas

A parallel plate capacitor in vacuum is in the charging condition. The radius of each plate is 5 cm. At an instant, the conduction current flowing through the wires is 0.4 A. What will be the displacement current between the plates at this time?

Also, calculate the displacement current density and evaluate the rate of change in the electric field between the plates. Calculate the induced magnetic field between the plates and plot it for a distance of 1--5 cm from the axis.

Displacement current is expressed in terms of electric flux, which in turn, can be obtained in terms of charge.

The displacement current equals the conduction current flowing through the wires, which is 0.4 Amperes.

Furthermore, the displacement current density can be calculated.

As the capacitor charges, the electric field between the plates increases, which is evaluated using displacement current density and the permittivity of free space.

As per the Ampere-Maxwell law, the magnetic field is induced between the capacitor plates, which is calculated for different distances from the axis and plotted as shown.

A parallel-plate capacitor with capacitance C, whose plates have area A and separation distance d, is connected to a resistor R and a battery of voltage V. The current starts to flow at t = 0. What is the displacement current between the capacitor plates at time t? From the properties of the capacitor, what is the corresponding real current?

To solve the problem, we can use the equations from the analysis of an RC circuit and Maxwell's version of Ampère's law.

For the first part of the problem, the voltage between the plates at time t is given by

Equation1

Suppose that the z-axis points from the positive plate to the negative plate. In this case, the z-component of the electric field between the plates as a function of time t is given by

Equation2

Therefore, the z-component of the displacement current I_dbetween the plates of the capacitor can be evaluated as

Equation3

where the capacitance Equation 4 is being used.

Further, to solve the second part of the above-stated problem, the current into the capacitor after the circuit is closed can be obtained by the charge on the capacitor, which in turn can be evaluated by using the expression for V_C. As a result, the real current into the capacitor is found to be the same as the displacement current.

Tags

Ampere Maxwell s Law Parallel plate Capacitor Capacitance Displacement Current Electric Field RC Circuit Voltage Real Current Charge On The Capacitor Time T

Do Capítulo 30:

article

Now Playing

30.14 : Lei de Ampère-Maxwell: Resolução de Problemas

Indução Eletromagnética

438 Visualizações

article

30.1 : Indução

Indução Eletromagnética

3.7K Visualizações

article

30.2 : Lei de Faraday

Indução Eletromagnética

3.7K Visualizações

article

30.3 : Lei de Lenz

Indução Eletromagnética

3.3K Visualizações

article

30.4 : FEM de Movimento

Indução Eletromagnética

3.0K Visualizações

article

30.5 : Dínamo de Disco de Faraday

Indução Eletromagnética

1.9K Visualizações

article

30.6 : Campos Elétricos Induzidos

Indução Eletromagnética

3.4K Visualizações

article

30.7 : Campos Elétricos Induzidos: Aplicações

Indução Eletromagnética

1.4K Visualizações

article

30.8 : Correntes de Foucault

Indução Eletromagnética

1.4K Visualizações

article

30.9 : Corrente de Deslocamento

Indução Eletromagnética

2.7K Visualizações

article

30.10 : Significado da Corrente de Deslocamento

Indução Eletromagnética

4.2K Visualizações

article

30.11 : Campos Electromagnéticos

Indução Eletromagnética

2.0K Visualizações

article

30.12 : Equação de Eletromagnetismo de Maxwell

Indução Eletromagnética

2.9K Visualizações

article

30.13 : Simetria nas Equações de Maxwell

Indução Eletromagnética

3.1K Visualizações

article

30.15 : Forma Diferencial das Equações de Maxwell

Indução Eletromagnética

339 Visualizações

See More

Copyright © 2025 MyJoVE Corporation. Todos os direitos reservados