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University Physics with Modern Physics

Hugh D. Young, Roger A. Freedman

Physics

14th edition Edition · 1596 pages

ISBN: 9780321973610

Chapter 4: Q15DQ (page 981)

Does Lenz’s law say that the induced current in a metal loop always flows to oppose the magnetic flux through that loop? Explain.

Short Answer

Expert verified

No, no induced current in a metal loop will flow to oppose the magnetic flux through the loop.

Step by step solution

01

Step 1:

According to Lenz, the direction of the induced current is such that it opposes the cause of it. Because the induced current is created by the changing flux, its direction opposes the change in flux. As a result, the induced current does not always have to resist the magnetic flux. It is in opposes the shift in magnetic flux.

No, no induced current in a metal loop will flow to oppose the magnetic flux through the loop.

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Most popular questions from this chapter

An 18-gauge copper wire (diameter 1.02 mm) carries a current

with a current density of $3.2 \times 10^{6} \frac{A}{m^{2}}$ . The density of free electrons for

copper is $8.5 \times 10^{28}$ electrons per cubic meter. Calculate (a) the current in

the wire and (b) the drift velocity of electrons in the wire.

Ordinary household electric lines in North America usually operate at 120 V . Why is this a desirable voltage, rather than a value considerably larger or smaller? On the other hand, automobiles usually have 12 V electrical systems. Why is this a desirable voltage?

When a resistor with resistance Ris connected to a 1.50-V flashlight battery, the resistor consumes 0.0625 W of electrical power. (Throughout, assume that each battery has negligible internal resistance.) (a) What power does the resistor consume if it is connected to a 12.6-V car battery? Assume that Rremains constant when the power consumption changes. (b) The resistor is connected to a battery and consumes 5.00 W. What is the voltage of this battery?

An idealized ammeter is connected to a battery as shown in Fig.

E25.28. Find (a) the reading of the ammeter, (b) the current through the $4.00 Ω$

resistor, (c) the terminal voltage of the battery.

Fig. E25.28.

CALC The region between two concentric conducting spheres with radii and is filled with a conducting material with resistivity $ρ$ . (a) Show that the resistance between the spheres is given by

$R = \frac{ρ}{4 π} (\frac{1}{a} - \frac{1}{b})$

(b) Derive an expression for the current density as a function of radius, in terms of the potential difference

V_{a b}

between the spheres. (c) Show that the result in part (a) reduces to Eq. (25.10) when the separation

L = b - a

between the spheres is small.

See all solutions

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