16.1 Maxwell’s equations and electromagnetic waves (Page 2/8)

University physics volume 2 Page 2 / 8

\oint_{C} \vec{B} \cdot d \vec{s} = μ_{0} I + ε_{0} μ_{0} \frac{d Φ_{E}}{d t}

and is independent of the surface S through which the current I is measured.

We can now examine this modified version of Ampère’s law to confirm that it holds independent of whether the surface $S_{1}$ or the surface $S_{2}$ in [link] is chosen. The electric field $\vec{E}$ corresponding to the flux $Φ_{E}$ in [link] is between the capacitor plates. Therefore, the $\vec{E}$ field and the displacement current through the surface $S_{1}$ are both zero, and [link] takes the form

\oint_{C} \vec{B} \cdot d \vec{s} = μ_{0} I .

We must now show that for surface $S_{2},$ through which no actual current flows, the displacement current leads to the same value $μ_{0} I$ for the right side of the Ampère’s law equation. For surface $S_{2},$ the equation becomes

\oint_{C} \vec{B} \cdot d \vec{s} = μ_{0} \frac{d}{d t} [ε_{0} \iint_{Surface S_{2}} \vec{E} \cdot d \vec{A}] .

Gauss’s law for electric charge requires a closed surface and cannot ordinarily be applied to a surface like $S_{1}$ alone or $S_{2}$ alone. But the two surfaces $S_{1}$ and $S_{2}$ form a closed surface in [link] and can be used in Gauss’s law. Because the electric field is zero on $S_{1}$ , the flux contribution through $S_{1}$ is zero. This gives us

\begin{matrix} ∯_{Surface S_{1} + S_{2}} \vec{E} \cdot d \vec{A} & = \iint_{Surface S_{1}} \vec{E} \cdot d \vec{A} + \iint_{Surface S_{2}} \vec{E} \cdot d \vec{A} \\ = 0 + \iint_{Surface S_{2}} \vec{E} \cdot d \vec{A} \\ = \iint_{Surface S_{2}} \vec{E} \cdot d \vec{A} . \end{matrix}

Therefore, we can replace the integral over $S_{2}$ in [link] with the closed Gaussian surface $S_{1} + S_{2}$ and apply Gauss’s law to obtain

\oint_{S_{1}} \vec{B} \cdot d \vec{s} = μ_{0} \frac{d Q_{in}}{d t} = μ_{0} I .

Thus, the modified Ampère’s law equation is the same using surface $S_{2},$ where the right-hand side results from the displacement current, as it is for the surface $S_{1},$ where the contribution comes from the actual flow of electric charge.

Displacement current in a charging capacitor

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

. (a) Find the displacement current between the capacitor plates at time t . (b) From the properties of the capacitor, find the corresponding real current

I = \frac{d Q}{d t}

, and compare the answer to the expected current in the wires of the corresponding RC circuit.

Strategy

We can use the equations from the analysis of an RC circuit ( Alternating-Current Circuits ) plus Maxwell’s version of Ampère’s law.

Solution

The voltage between the plates at time t is given by

$V_{C} = \frac{1}{C} Q (t) = V_{0} (1 - e^{− t / R C}) .$

Let the z -axis point from the positive plate to the negative plate. Then the z -component of the electric field between the plates as a function of time t is

$E_{z} (t) = \frac{V_{0}}{d} (1 - e^{− t / R C}) .$

Therefore, the z-component of the displacement current $I_{d}$ between the plates is

$I_{d} (t) = ε_{0} A \frac{\partial E_{z} (t)}{\partial t} = ε_{0} A \frac{V_{0}}{d} \times \frac{1}{R C} e^{− t / R C} = \frac{V_{0}}{R} e^{− t / R C},$

where we have used $C = ε_{0} \frac{A}{d}$ for the capacitance.
From the expression for $V_{C},$ the charge on the capacitor is

$Q (t) = C V_{C} = C V_{0} (1 - e^{− t / R C}) .$

The current into the capacitor after the circuit is closed, is therefore

$I = \frac{d Q}{d t} = \frac{V_{0}}{R} e^{− t / R C} .$

This current is the same as $I_{d}$ found in (a).

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Maxwell’s equations

With the correction for the displacement current, Maxwell’s equations take the form

\oint \vec{E} \cdot d \vec{A} = \frac{Q_{in}}{ε_{0}} (Gauss’s law)

\oint \vec{B} \cdot d \vec{A} = 0 (Gauss’s law for magnetism)

\oint \vec{E} \cdot d \vec{s} = - \frac{d Φ_{m}}{d t} (Faraday’s law)

\oint \vec{B} \cdot d \vec{s} = μ_{0} I + ε_{0} μ_{0} \frac{d Φ_{E}}{d t} (Ampère-Maxwell law) .

Once the fields have been calculated using these four equations, the Lorentz force equation

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Practice Key Terms 2

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Source: OpenStax, University physics volume 2. OpenStax CNX. Oct 06, 2016 Download for free at http://cnx.org/content/col12074/1.3

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