A solid conducting sphere of radius 3.2 cm has a charge of 29 nC distributed uniformly over its surface. Let A be a point 1.3 cm from the center of the sphere, S be a point on the surface of the sphere, and B be a point 6.6 cm from the center of the sphere. What are the electric potential differences (a)VS – VB and (b)VA – VB?
A solid conducting sphere of radius 3.2 cm has a charge of 29 nC distributed uniformly...
A nonconducting solid sphere of radius 2.10 cm carries a uniformly distributed positive charge of 8.50 times 10^-9 C. Calculate the magnitude of the electric field at a point 1.90 cm away from the center of the sphere. Incompatible units. No conversion found between "N/M" and the required units. Calculate the magnitude of the electric field at a point 3.60 cm away from the center of the sphere. Assume that the sphere is conducting. Calculate the magnitude of the electric...
A solid conducting sphere has a radius of 10.7 cm and a net electrical charge of 4.06 nC. What is the magnitude of the electric field at a distance 18.6 cm from the sphere's center? Select one a. 10.5 N/C b. 1.9664 N/C c. 1050 N/C d. 196 N/G e. 3190 N/C 2. A hollow conducting sphere has an inner radius of 5.38 cm and an outer radius of 8.637 cm. The sphere has a net electric charge of -6.87...
A solid conducting sphere of radius 2 cm has a charge of 8 μC. A conducting spherical shell of inner radius 4 cm and outer radius 5 cm is concentric with the solid sphere and has a charge of -4 μC Find: a) The electric field at r = 1 cm from the center of this charge configuration. b) The electric field at r = 3 cm from the center of this charge configuration c) The electric field at r =...
A nonconducting solid sphere of radius 2.20 cm carries a uniformly distributed positive charge of 7.00×10-9 C. Calculate the magnitude of the electric field at a point 1.40 cm away from the center of the sphere. Calculate the magnitude of the electric field at a point 3.20 cm away from the center of the sphere.
A solid insulating sphere of radius 5.00 cm is centered at the origin. It carries a total charge of 2.00 C uniformly distributed through its volume. Concentric with this sphere is an uncharged conducting shell whose inner and outer radii are 8.00 cm and 10.0 cm respectively. a What is the electric field (magnitude and direction) 1.00 cm from the origin b How much charge resides on the inner surface of the conductor c What is the electric field (magnitude and...
A solid non-conducting sphere (R = 10 cm) has a charge of uniform density 50 nC/m3 uniformly distributed throughout its volume. (a) Determine the magnitude of the electric field 20 cm from the center of the sphere. (b) Determine the magnitude of the electric field 5 cm from the center of the sphere. Hint: first calculate the charges inside the assumed Gaussian surfaces, assume π = 3. Answer: 45 N/C, 90 N/C.
A long, solid, conducting cylinder has a radius of 2.0 cm. The electric field at the surface of the cylinder is 780 N/C, directed radially outward. Let A, B, and C be points that are 1.1 cm, 2.0 cm, and 8.2 cm, respectively, from the central axis of the cylinder. What are (a) the magnitude of the electric field at C and the electric potential differences (b)VB – VC and (c)VA – VB?
A solid conducting sphere has a radius of 12.3 cm and a net electrical charge of 4.75 nC. What is the magnitude of the electric field at a distance 21.8 cm from the sphere's center?
20) A solid conducting sphere of 10-cm radius has a net charge of 18 nC. If the potential at infinity is taken as zero, what is the potential at the center of the sphere? A)2. I μν B) 16 μν C) 1.6x10VD) >1.6x104 V E) 13 μν
2. Gauss' Law See Figure 1. A solid, conducting sphere of radius a has total charge (-)2Q uniformly distributed along its surface, where Q is positive. Concentric with this sphere is a charged, conducting spherical shell whose inner and outer radii are b and c, respectively. The total charge on the conducting shell is (-)8Q. Find the electric potential for r < a. Take the potential out at infinity to be 0.