Two positively charged metal spheres are suspended from the same hook by light strings of equal...
Two metal spheres of identical mass m = 4.60 g are suspended by light strings 0.500 m in length. The left-hand sphere carries a charge of 0.865 µC, and the right-hand sphere carries a charge of 1.49 µC. What is the equilibrium separation between the centers of the two spheres?
Two metal spheres of identical mass m = 3.40 g are suspended by light strings 0.500 m in length. The left-hand sphere carries a charge of 0.845 µC, and the right-hand sphere carries a charge of 1.55 µC. What is the equilibrium separation between the centers of the two spheres?
Two small metallic spheres, each of mass m-0.25 g, are suspended as pendulums by light strings from a common point as shown in the figure below. The spheres are given the same electric charge, and it is found that they come to equilibrium when each string is at an angle of θ-4.80 with the vertical. If each string has length L 38.0 cm, what is the magnitude of the charge on each sphere?
Two small metallic spheres, each of mass m-0.40 g, are suspended as pendulums by light strings from a common point as shown in the figure below. The spheres are given the same electric charge, and it is found that they come to equilibrium when each string is at an angle of θ = 7.5° with the vertical. If each string has length L 28.0 cm, what is the magnitude of the charge on each sphere? nC
Two metal spheres, each of mass 0.55 g, are suspended by massless strings from a common pivot point at the ceiling, as shown in the figure. When both spheres carry the same electric charge, we find that they come to an equilibrium when each string is at an angle of θ = 4.0° with the vertical. If each string is 26 cm long, what is the amount of the charge on each sphere? (Enter the magnitude in nC.)
Two metal spheres, each of mass 0.65 g, are suspended by massless strings from a common pivot point at the ceiling, as shown in the figure. When both spheres carry the same electric charge, we find that they come to an equilibrium when each string is at an angle of θ = 4.0° with the vertical. If each string is 30 cm long, what is the amount of the charge on each sphere? (Enter the magnitude in nC.)
Two metal spheres, each of mass 0.40 g, are suspended by massless strings from a common pivot point at the ceiling, as shown in the figure. When both spheres carry the same electric charge, we find that they come to an equilibrium when each string is at an angle of θ = 7.5° with the vertical. If each string is 26 cm long, what is the amount of the charge on each sphere? (Enter the magnitude in nC.)
Two metal spheres, each of mass 0.15 g, are suspended by massless strings from a common pivot point at the ceiling, as shown in the figure. When both spheres carry the same electric charge, we find that they come to an equilibrium when each string is at an angle of θ = 4.0° with the vertical. If each string is 21 cm long, what is the amount of the charge on each sphere? (Enter the magnitude in nC).
Two metal spheres, each of mass 0.30 g, are suspended by massless strings from a common pivot point at the ceiling, as shown in the figure. When both spheres carry the same electric charge, we find that they come to an equilibrium when each string is at an angle of θ·4.5. with the vertical. If each string is 20 cm long, what is the amount of the charge on each sphere? (Enter the magnitude in nc.) nC
The figure below shows two identical conducting spheres, each with charge q, suspended from light strings of length L. If the equilibrium angle the strings make with the vertical is theta, what is the mass m of the spheres? (Use any variable or symbol stated above along with the following as necessary: g for the acceleration due to gravity, and k for the Coulomb constant.)