A rectangular loop of wire with dimensions 2.43 cm by 8.38 cm and resistance 0.593 Ω is being pulled to the right out of a region of uniform magnetic field. The magnetic field has magnitude 3.01 T and is directed into the plane of the following figure(Figure 1).
Part A
At the instant when the speed of the loop is 3.09 m/s and it is still partially in the field region, what is the magnitude of the force the magnetic field exert on the loop?
Part B
What is the direction of the force the magnetic field exert on the loop?
A rectangular loop of wire with dimensions 2.43 cm by 8.38 cm and resistance 0.593 Ω
A rectangular loop of wire with dimensions 2.12 cm by 8 50 cm and resistance 0.576 Ω is being pulled to the right out of a region of uniform magnetic field. The magnetic field has magnitude 3.27 T and is directed into the plane of the following figure(Figure 1) Part A At the instant when the speed of the loop is 3.00 m/s and it is still partially in the field region, what is the magnitude of the force the magnetic field...
A rectangular loop of wire with dimensions 1.80 cm by 7.00 cm
and resistance 0.800 Ω is being pulled to the right out of a region
of uniform magnetic field. The magnetic field has magnitude 2.60 T
and is directed into the plane of (figure 1).
A) At the instant when the speed of the loop is 3.00 m/s and it
is still partially in the field region, what is the magnitude of
the force that the magnetic field exerts...
A circular loop of wire with radius 0.0270 m and resistance 0.320 Ω is in a region of spatially uniform magnetic field, as shown in the following figure(Figure 1). The magnetic field is directed into the plane of the figure. At t = 0, B = 0. The magnetic field then begins increasing, with B(t) =( 0.400 T/s3)t3 .Part A What is the current in the loop (magnitude) at the instant when B = 1.38 T? Part B What is the direction of the...
Please answer both parts correctly, with correct units, and show
your work! thanks!
Constants A rectangular loop of wire with dimensions 1.80 cm by 8.00 cm and resistance 0.800 is being pulled to the right out of a region of unitorm magnetic field. The magnetic field has magnitude 2.80 T and is directed into the plane of (Figure 1) At the instant when the speed of the loop is 3.00 m/s and it is still partially in the field region,...
Part of a single rectangular loop of wire with dimensions shown in the (Figure 1) is situated inside a region of uniform magnetic field of 0.740 T . The total resistance of the loop is 0.780 Ω . Calculate the force required to pull the loop from the field (to the right) at a constant velocity of 5.20 m/s . Neglect gravity.
Part of a single rectangular loop of wire with dimensions shown in the figure (Figure 1) is situated inside a region of uniform magnetic field of 0.336 T . The total resistance of the loop is 0.532 Ω . Calculate the force required to pull the loop from the field (to the right) at a constant velocity of 1.59 m/s . Neglect gravity.
A circular loop of wire with radius 0.0290 m and resistance 0.370Ω is in a region of spatially uniform magnetic field, as shown in the following figure(Figure 1). The magnetic field is directed into the plane of the figure. At t = 0, B = 0. The magnetic field then begins increasing, with B(t) = (0.400 T/s3)t3 Part A What is the current in the loop (magnitude) at the instant when B = 1.29 T?
A rigid wire with resistance of
0.111 Ω forms a nearly complete circular loop (see figure below). A
8.38 V battery is connected between points a and b. Find the torque
exerted on the wire by a magnetic field of magnitude 0.400 T,
directed to the right, in the plane of the loop.
0.400 Ť
A flat rectangular loop of wire is placed between the poles of a
magnet, as shown in the figure. It has dimensions w =
0.60 m and L = 1.0 m, and carries a current I = 2.0 A in the
direction shown. The magnetic field due to the magnet is uniform
and of magnitude 0.80 T. The loop rotates in the magnetic field and
at one point the plane of the loop is parallel to the field, as
shown.A)...