Two parallel circular rings, each 10.0 cm in radius, are 1.00 mm apart. At this point, a current of 145A flows clockwise in the upper ring and 145A in the lower one counterclockwise. Then, the upper ring has a mass of 0.02119 kg. If the force acting on the upper ring is only the magnetic force acting on the lower ring and the gravity of the ring, what is the acceleration of this ring? (However, g=9.80m/s^2)
Two parallel circular rings, each 10.0 cm in radius, are 1.00 mm apart. At this point,...
Two parallel circular rings of radius R = 21 cm have their
centers on the x axis separated by a distance l = 10.4 cm. If each
ring carries a uniformly distributed charge Q = 0.015 ?C, find the
electric field E at the point on the x axis at x = 3 cm. Give a
positive answer if the electric field points to the right, negative
if to the left.
Find the electric field E at x = 16.9...
The circular disk has a 200 mm radius and mass of 25 kg. The radius of gyration k about the center of gravity is 175mm. The inner radius of the disk is 75 mm. A steady force of T=30 Newtons is applied cord wrapped around the inner radius. 3. angle 0 17° to a at an Find: The angular acceleration of the disk, a) b) The acceleration of the mass centre G The friction force F from the ground acting...
Two infinite parallel wires, a distane of 2x apart, each have a current I flowing in opposite directions. Now imagine placing a circular ring of wire with a current of 4I, centered at the midpoint m. a) What is the radius of this ring so the magnetic field at m is 0? b) Does the current flow clockwise or counter clockwise.
In the diagram P1 and P2 are two parallel horizontal plates that
are 5.4 mm apart in a vacuum and have a potential difference of 189
volts maintained between them, the upper plate being positive.
Also, there is a horizontal magnetic field of 0.068. A horizontal
beam of electrons is directed between the plates so that it is
moving at right angles to the magnetic field as shown.
a. Determine the magnitude of the force due to the electric
field...
Please show all work!
A Two parallel rings, each of radius R, are separated by a distance R. A positive charge^+Q is uniformly distributed around the upper ring and a negative charge^-Q is uniformly distributed around the lower ring. Let z be the vertical coordinate, with z = 0 taken to be the center of the lower negatively charged ring. What is the direction and magnitude of the electric field at the point A on the vertical axis, a distance...
4. Consider a circular loop of wire with a mass m and a radius R. The circular loop is vertical such that gravitational force on the loop points straight down. You may assume this is near the surface of the earth such that the force of gravity has a magnitude FGl mg. The upper half of the circular wire is immersed in a uniform magnetic field B pointing into the page. In the figure below this corresponds to the region...
Two long, straight parallel wires
are 10.0 cm apart and carry 3.20 A currents in the same direction
(see the figure).
Find the direction of the magnetic field at point P1, midway
between the wires.
Find the magnitude of the magnetic field at point P1, midway
between the wires.
Find the direction of the magnetic field at point P2, 25.0 cm to
the right of P1.
Find the magnitude of the magnetic field at point P2, 25.0 cm to
the...
Two long thin parallel wires 13.0 cm apart carry 29-A currents
in the same direction.
1) Determine the magnitude of the magnetic field vector at a
point 10.0 cm from one wire and 6.0 cm from the other
2) Determine the direction of the magnetic field vector at that
point. Example: θ= ... degrees, measured counterclockwise from the
positive x axis
13.0 cm 10.0 cm $6.0 cm
Problem 6- Two long straight parallel wires are 10.0 cm apart and carry 4.00 A currents in the same direction. Find the magnitude and direction of the magnetic field at a) Point Pu, midway between the wires. b) Point P2, 25.0 cm to the right of P1 10.0 cm
Two long thin parallel wires 13.0 cm apart carry 24-Acurrents in
the same direction.
Part A:
Determine the magnitude of the magnetic field vector at a point
10.0 cm from one wire and 6.0 cm from the other (Figure 1) .
Part B:
Determine the direction of the magnetic field vector at that
point.
degrees, measured counterclockwise from the positive x
axis