Three bodies of identical mass M = 15 kg form the vertices of an equilateral triangle of side L = 0.99 m and rotate in circular orbits about the center of the triangle. They are held in place by their mutual gravitation. a. What is orbital radius of each? b. What is the magnitude of the inward radial force on each mass? c. What is the orbital frequency of each mass?
Three bodies of identical mass M = 15 kg form the vertices of an equilateral triangle...
Three identical point charges, Q = +5 C are placed at the vertices of an equilateral triangle as shown in the figure. The length of each side of the triangle is d = 1.5 cm I think the answer is 3.46E7 upwards but I'm not sure SECTION B Do all the Problems) 1) Three identical point charges, Q +5HC are placed at the vertices of an equilateral triangle as shown in the figure. The length of each side of the...
Three identical masses (m = 3.25 x 10^8 kg) are held at the corners of an equilateral triangle, d = 0.3m on each side. What is the magnitude of force exerted on the top mass by two other masses?
Consider an equilateral triangle with sides of length 5cm where each of the three vertices carry a charge. The top vertex carries a charge of +9.0µC, while the bottom vertices each carry a charge of?5.0µC. (a) (7 points) What is the magnitude and direction of the electric field at the center of the triangle? (b) (3 points) If the center of the triangle contained a proton, what would the force be of the charged vertices on the proton?
Three uniform spheres are placed at the vertices of an equilateral triangle. The sphere at vertex A has a mass m. The mass of each sphere at vertices B and C are known to be the same mass M. Let R be the distance from the centre of the triangle to one of the three vertices. (a) A fourth sphere is placed at the centre of the equilateral triangle It is known that the net force on the fourth sphere...
Three light rods of negligible mass are joined to form an equilateral triangle of length L = 1.90 m. Three masses m1 = 5.00 kg, m2 = 7.00 kg, and m3 = 9.00 kg are fixed to the vertices of this triangle as shown in the diagram below. Treat the masses as point particles.(a) What is the moment of inertia of the system about an axis lying in the plane of the triangle, passing through the midpoint of one side...
Consider an equilateral triangle, with side length 0.693 m. At two of the vertices of this triangle, there are long straight wires carrying a current of 8.11 A out of the page. Find the magnitude of the magnetic field, in T, at the third vertex.
Three identical point charges each of charge q are located at the vertices of an equilateral triangle as shown in the figure. The distance from the center of the triangle to each vertex is a. (a) Show that the electric field at the center of the triangle is zero. (b) Find a symbolic ex pression for the electric potential at the center of the triangle. (c) Give a physical explanation of the fact that the electric potential is not zero,...
Three identical point charges each of charge q are located at the vertices of an equilateral triangle as shown in the figure. The distance from the center of the triangle to each vertex is a. (a) Show that the electric field at the center of the triangle is zero. (b) Find a symbolic ex pression for the electric potential at the center of the triangle. (c) Give a physical explanation of the fact that the electric potential is not zero,...
1. (25 pts.) Three particles are at the vertices of a rigid, massless equilateral triangle, whose sides are L = 4.0 m. Their masses are mi = 10 kg, m2 = 20 kg and m3 = 30 kg. a. Find the x and y coordinates of the center of mass of the system, with respect to the point P halfway along the base. b. Find the moment of inertia if the system is free to rotate around an axis down...
3. Consider three particles with identical charges q at the corners of an equilateral triangle from side to side as in the figure. a. Calculate the electrical potential at the top load position due to the other two charges How does this result change if the calculation is made at the position of the load right? b. At what point, if any, is the potential of this zero-load configuration? c. Calculate the work to be done to place a load...