Two small spheres, each of mass 3.00 g, are suspended by light strings 10.0 cm in...
Two 2.30-g spheres are suspended by 11.5-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of −4.00 ✕ 10−8 C and +4.00 ✕ 10−8 C, determine the electric field intensity that enables the spheres to be in equilibrium at θ = 16.0°. Two 2.30-g spheres are suspended by 11.5-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of...
Two 2.70-g spheres are suspended by 22.5-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of −3.00 ✕ 10−8 C and +3.00 ✕ 10−8 C, determine the electric field intensity that enables the spheres to be in equilibrium at θ = 13.0°. _____ N/C
Two 2.50-g spheres are suspended by 17.0-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of −6.00 ✕ 10−8 C and +6.00 ✕ 10−8 C, determine the electric field intensity that enables the spheres to be in equilibrium at θ = 15.0°. _____ N/C ?
Two small metallic spheres, each of mass m 0.192 9, are suspended as pendulums by light strings of length L as shown in the figure below. The spheres are given the same electric charge of 7.1 nC, and they come to equilibrium when each string is at an angle of θ = 5.10° with the vertical. How long are the strings? Your response differs significantly from the correct answer. Rework your solution from the beginning and check each step carefully....
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 t magnitude of the charge on each sphere? 0.0186e-8 X Your response...
Two 3.10-9 spheres are suspended by 16.0-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of -6.50 x 10-8 C and +6.50 X 10-ºc, determine the electric field intensity that enables the spheres to be in equilibrium at 0 = 11.0°. 4. 9 142682.19 x Your response differs from the correct answer by more than 10%. Double check your calculations. N/C
Two 4.00-g spheres are suspended by 22.0-cm-long light strings (see the figure). A uniform electric field is applied in the x- direction. If the spheres have charges of -3.50 x 10-8 C and +3.50 x 10-8 c, determine the electric field intensity that enables 12.0° the spheres to be in equilibrium at 0 ie 4.0 2.38e5 Your response differs from the correct answer by more than 10%. Double check your calculations. N/C
Two small metallic spheres, each of mass m = 0.35 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 = 4.70 with the vertical. If each string has length L = 39.0 cm, what is the magnitude of the charge on each sphere? Your response...
Two small metallic spheres, each of mass m -0.218 9, are suspended as pendulums by light strings of length as shown in the figure below. The spheres are given the same electric charge of 7.4 nC, and they come to equilibrium when each string is at an angle of 0 - 5.25" with the vertical. How long are the strings? Tx Enter a numbe differs significantly from the correct answer. Rework your solution from the beginning and check each step...
Two 1.70-g spheres are suspended by 11.5-cm-long light strings (see the figure). A uniform electric field is applied in the x-direction. If the spheres have charges of -3.50 x 10-8 C and +3.50 x 10-8 C, determine the electric field intensity that enables the spheres to be in equilibrium at 0 = 13.0°. È 4.9 INC