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...
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 0.0270 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,...
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
At t = 0, a rectangular coil of resistance R = 2 Ω and dimensions W = 3 cm and L = 8 cm enters a region of constant magnetic field B = 1.6 T directed into the screen as shown. The length of the region containing the magnetic field is LB = 15 cm. The coil is observed to move at constant velocity v = 5 cm/s. What is the force required at time t = 0.8 sec to...
A very long, rectangular loop of wire can slide without friction on a horizontal surface. Initially the loop has part of its area in a region of uniform magnetic field that has magnitude B = 3.30 T and is perpendicular to the plane of the loop. The loop has dimensions 4.00 cm by 60.0 cm, mass 26.0 g , and resistance R = 7.00×10−3 Ω . The loop is initially at rest; then a constant force Fext = 0.180 N...