(3 points) Two superconducting and frictionless rails a distance I apart are connected by a super...
A conducting bar slides without friction on two parallel horizontal rails that are 50 cm apart and connected by a wire at one end. The resistance of the bar and the rails is constant and equal to 0.10 0. A uniform magnetic field is perpendicular to the plane of the rails. A 0.080-N force parallel to the rails is required to keep the bar moving at a constant speed of 0.50 m/s. What is the magnitude of the magnetic field...
A conducting pustion bar slides without friction on two parallel horizontal rails that are 50cm apart and connected by a wire at one end. The resistance of the bar and the rails is constant and caual to 0.10 hat uniform magnetic field is perpendicular to the Plane of the rails of 0.080-N force parallel to the rails is reauired to keep the at a constant speed of c. 50 m/s. What is the magnitude of the magnetic field in Tesla?...
A conductiong bar of mass m is place on two long conducting rails a distance l apart. The rails are inclined at an angle ? with respect to the horizontal, and the bar is able to slide on the rails with negligible friction. The bar and rails are in a uniform and constant magnetic field of magnitude B oriented perpendicular to the incline. A resistor of resistance R connects the upper ends of the rails and completes the circuit as...
A pair of conducting, parallel, frictionless rails is mounted on an insulating platform. The distance between the rails is L = 0.20 m. The rails are connected on one end by a R = 10.12 resistor. A conducting bar of mass 1.2 kg can slide on the rails without friction. When the conducting bar is at x = 0, the enclosed area of the loop is 0.03 m2. There is zero resistance in the conducting bar or rails. A uniform...
Two parallel conducting rails with negligible resistance are
41.0 cm apart and are connected together at one end by an
18.8Ω resistor. A conducting bar, also with negligible
resistance, is free to slide along the rails. The system is in a
region where a 315 mT magnetic field points perpendicular to
the plane of the rails, as shown in (Figure 1). If the bar is
pulled along the rails at 5.69 m/s, what's the current in the
circuit comprising the...
A pair of conducting, parallel, frictionless rails is mounted on an insulating platform. The distance between the rails is L=0.30 m. A light conducting bar can slide on the rails without friction. When the conducting bar is at x = 0, the enclosed area of the loop is 0.03 m². There is zero resistance in the conducting bar or rails, the rails are connected on one end by a R=1.5 resistor. A uniform magnetic field of B -0.25 T is...
As shown in the figure, two frictionless conducting rails (#1 and #2) are attached to a 20.0° incline such that the inside edges are 80.0 cm apart. A copper bar with a mass of 0.237 kg slides (without friction) at a constant speed down the conducting rails. Sliding bar Conducting rails If there is a vertical magnetic field of 0.0406 T in magnitude in the region of the incline, determine the magnitude of the current I that flows through the...
Two parallel conducting rails a distance l apart are connected
at one end by a resistance R in series with battery of emf E. A
conducting bar completes the circuit, joining the two rails
electrically but free to slide along them. The whole circuit is
perpendicular to a uniform magnetic field B, as shown in (Figure
1). The bar is initially at rest, and nothing is pulling it.
Find an expression for the initial value of the current in the...
A conducting bar of mass m is placed on two long conducting rails a distance l apart. The rails are inclined at an angle theta with respect to the horizontal, andthe bar is able to slide on the rails with negligible friction. The bar and rails are in a uniform and constant magnetic field of magnitude B orientedperpendicular to the incline. A resistor of resistance R connects the upper ends of the rails and completes the circuit as shown. The...
A conducting bar moves along frictionless conducting rails
connected to a 4.00 omega resistor. The length of the bar is 1.60m
and a uniform magnetic field of 2.20T is applied perpendicular to
the paper pointing outward as shown
a) What is the applied force required to move the bar to the
right with a constant speed of 6.00 m/s?
b) At what rate is energy dissipated in the 4.00 ohm
resistor?
A conducting bar moves along frictionless conducting rails connected...