Here we'll see that an emf can be induced by the motion of the conductor in a static magnetic field. The U-shaped conductor in (Figure 1) lies perpendicular to a uniform magnetic field B⃗ with magnitude B=0.75T , directed into the page. We lay a metal rod with length L=0.10m across the two arms of the conductor, forming a conducting loop, and move the rod to the right with constant speed v=2.5m/s . What is the magnitude of the resulting emf?

With the given magnetic field and rod length, what must the speed be if the induced emf has magnitude 0.73 V ?

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moya1316 moya1316 · Answer 1 · 2020-02-07T08:19:12+01:00

Answer:

a) ΔV = 0.1875 V , b) v = 9.73 m / s

Explanation:

For this exercise we can use Necton's second law, as the speed is constant the forces on the driver are equal

[tex]F_{E} - F_{B}[/tex] = 0

[tex]F_{E}[/tex] = F_{B}

q E = q v B

E = v B

The electrical force induced in the conductor is

ΔV = E l

ΔV = v B l

Let's calculate

ΔV = 2.5 0.75 0.10

ΔV = 0.1875 V

b) If ΔV = 0.73 what speed should it have

v = DV / B l

v = 0.73 / 0.75 0.1

v = 9.73 m / s