A 5.4 g charged insulating ball hangs on a 0.85 cm long string in a uniform horizontal electric field as shown in the figure. Given the charge on the ball is 35 μC , find the strength of the field in N/C.
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A 5.4 g charged insulating ball hangs on a 0.85 cm long string in a uniform horizontal electric field as shown in the figure.
Given the charge on the ball is 35 μC , find the strength of the field in N/C.
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- A conducting sphere is placed within a conducting spherical shell. The conductors are in electrostatic equilibrium. The inner sphere has a radius of 1.50 cm, the inner radius of the spherical shell is 2.25 cm, and the outer radius of the shell is 2.75 cm. The inner sphere has a charge of 228 nC and the spherical shell has zero net charge. What is the electric field at a point 3.80 cm from the center? Enter a positive answer if the electric field is directed away from the center and a negative answer if the electric field is directed toward the center.A spherical conductor of radius a = 1.5 cm with a charge Q = -20 nC. At the center of the conductor sphere is a hollow insulator sphere whose inner radius is b= 2 cm and outer radius is c = 3 cm (see picture). This insulating ball is given a charge of q = + 30 nC. Using Gauss's law, determine the location of the points where the electric field is zero!A very large (can be considered infinite) plastic sheet is uniformly charged. The charge in 1.00 m2 area of the sheet is Incasured to be 4.71 E-6 C. What is the electric field magnitude at a point 2.14B-2 m away from the sheet (answer a positive number in N/C)? Physics constants: Number = = 3.14 Coulomb constant k = 1/(476) = 8.99E9 N•m/C2 Permittivity of vacuum &g = 8.85B-12
- A charged cork ball of mass 2.50 g is suspended on a light string in the presence of a uniform electric field as shown in the figure below. When E = (2.00 î + 4.60 ĵ) ✕ 105 N/C, the ball is in equilibrium at ? = 37.0°. Find the charge on the ball. Find the tension in the string.A conducting sphere is placed within a conducting spherical shell. The conductors are in electrostatic equilibrium. The inner sphere has a radius of 1.50 cm, the inner radius of the spherical shell is 2.25 cm, and the outer radius of the shell is 2.75 cm. The inner sphere has a charge of 228 nC and the spherical shell has zero net charge. What is the electric field at a point 3.80 cm from the center? Enter a positive answer if the electric field is directed away from the center and a negative answer if the electric field is directed toward the center.In the figure a thin glass rod forms a semicircle of radius r = 5.94 cm. Charge is uniformly distributed along the rod, with +q = 4.76 pc in the upper half and -q = -4.76 pC in the lower half. What is the magnitude of the electric field at P, the center of the semicircle? Number i Units + P
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