We need at least 10 more requests to produce the answer.
0 / 10 have requested this problem solution
The more requests, the faster the answer.
Phys 0600 Q21W20C Quiz - Ch. 21 Name 4.[6 marks] A conductor carries a current of...
Now consider two very long, parallel conductors separated by a distance 3b. Conductor #1 carries current / toward the top of the page, and Conductor #2 carries current 9/ toward the top of the page. (Let / = 6.00 A and b = 1.00 cm, as above.) (6.) (0.99 point) What is the magnitude of the magnetic force per unit length (in N/m) on Conductor #1? (7.) [0.36 point] What is the magnitude of the magnetic force per unit length...
Now consider two very long parallel conductors separated by a distance 3b. Conductor #1 carries current / toward the top of the page, and Conductor #2 carries current 91 toward the top of the page. (Let / = 6.00 A and b = 1.00 cm, as above.) (6.) (0.99 point) What is the magnitude of the magnetic force per unit length (in N/m) on Conductor #1? (7.) 10.36 point What is the magnitude of the magnetic force per unit length...
4)Find the direction of the magnetic field acting on the
positively charged particle moving in the various situations shown
in the figure below if the direction of the magnetic force acting
on it is as indicated.
(a) ---Select From the Options Below---
-downward
-upward
-out of the page
-to the right
-to the left
-into the page
(b) ---Select From the Options Below---
-into the page
-downward
-to the right
-out of the page
-to the left
-upward
(c) ---Select From the Options...
(8c28p46) A long, rigid conductor, lying along the x axis, carries a current of 7.0 A in the negative direction. A magnetic field B is present, given by B = 4.0i + 9.0x2 j , with x in meters and B in mT. Calculate the k-component of the force on the 2 m segment of the conductor that lies between x = 1.0 m and x = 3.0 m.
I
only need help with questions 4,5,6,7, and 8. thanks
Magnetic field and Magnetic Force due to a (long, straight) current PHYS 181 - in class problem set An infinitely long conductor carrying current is bent at a right angle as shown in Figure 1. Point P is located a distance b from the corner of the wire. Only one section of this current contributes to the magnetic field at pt. P. Why? The general formula (derived from the Biot-Savart...
Question 6 [5 marks] A rectangular loop with sides l = 30 cm and w 10 cm carries a current, I, of 2 A and lies centered in the xy-plane as shown below. The loop is in a region where there is a uniform magnetic field. The magnetic field is given by B (2 a3 ay + 4 az) x 102 Wb/m2. Determine the total force acting on the loop and the torque acting on the loop.
Question 6 [5...
4) A long straight wire carries current i = 2.0 A. A triangular loop (w = 0.050 m and t = 0.100 m) also carries the same current and is located at distance x = 0.025 m from the straight wire as shown. Recall that the magnetic field due to a long straight wire is given by B Ho 21 4r where r is the perpendicular distance from the wire. Note: Ho/472 = 1 x 10-?T.m/A. a) Determine the magnitude...
A square loop of wire carries a current I. Current is flowing in
a counterclockwise direction as shown.
16) If this loop is placed in a
uniform magnetic field pointing out the page, what is the direction
of the net force on the loop?
up
down
left
right
zero
17) Now the loop is placed near a
horizontal wire with current moving to the left. If the horizontal
wire is right below the loop (in the plane of the page), what is...
A long, straight wire perpendicular to this page carries a current of 4.62 A directed into the page. Find the magnetic field at the following points, all 10.5 cm from the wire. (a) 10.5 cm to the left of the wire magnitude direction (b) 10.5 cm directly below the wire magnitude direction (c) 10.5 cm to the right of the wire magnitude direction (d) 10.5 cm directly above the wire magnitude direction
An infinitely long conductor carrying current is bent at a right angle as shown in Figure 1. Point Pis located a distance b from the corner of the wire. Only one section of this current contributes to the magnetic field at pt. P. Why? The general formula (derived from the Biot-Savart Law) for the magnitude of the magnetic field a distance a away from a thin, straight conductor is: B = f (sin 8, - sin 02) For this problem,...