Question 10 (1 point) Q = 13.0 x 10^-11 C of charge is uniformly distributed on...
Charge Q = 7.00 μC is distributed uniformly over the volume of an insulating sphere that has radius R = 13.0 cm . A small sphere with charge q=+ 2.00 μC and mass 6.00×10−5kg is projected toward the center of the large sphere from an initial large distance. The large sphere is held at a fixed position and the small sphere can be treated as a point charge. What minimum speed must the small sphere have in order to come...
.1.Positive charge Q is distributed uniformly along the z-axis from x = 0 to x = a. A positive point charge q is located on he positive z-axis at a distance d to the right of the origin.(a) Calculate the electric potential produced by the charge distribution Q at x = d. (b) Develop an expression for the potential energy that would be added to the system by bringing a charge q from infinity to x = d. (c) Assuming the charges...
A total electric charge of 3.5nC is distributed uniformly over the surface of a metal sphere with a radius of 24cm. If the potential is zero at a point at infinity, find the value of the parental at the distances 48cm, 24cm, 12cm.
Charge Q = 8.00 μC is distributed uniformly over the volume of an insulating sphere that has radius R = 14.0 cm . A small sphere with charge q=+3.00 μC and mass 6.00.×10−5kg is projected toward the center of the large sphere from an initial large distance. The large sphere is held at a fixed position and the small sphere can be treated as a point charge. part a) What minimum speed must the small sphere have in order to...
Name 1. (12) An isolated charge metal sphere of diameter 10 cm has a potential of 8000 V relative to V 0.0 at infinity. a. (11) Derive an expression that calculates the energy density in the electric field on the surface of the sphere. answer (1) What is the numerical value of the energy density. b. answer
Charge Q = +4.00 μC is distributed uniformly over the volume of an insulating sphere that has radius R = 5.00 cm. What is the potential difference between the center of the sphere, V(0) and the surface of the sphere, V(R)? Solve by finding the E-field inside the insulating sphere using Gauss law, and then find the potential difference.
A total charge Q is uniformly distributed over the surface of two concentric con- ductive spheres of radii Ri R2 with the same density σ. To be clear, qi is on the smaller sphere, g2 on the larger sphere, and Q2. What are the electric field and the potential everywhere? What is the value of Q if one needs 10.J of work to move a positive charge of 1Coulumb from infinity to the center of the くHo spheres? A total...
A nonconducting sphere has a radius R=9.5 cm and uniformly distributed charge q=5.5e-12 C. Take the electric potential at the sphere's center to be zero. What is V at radial distance r=5.8 cm?
A nonconducting sphere has a radius R=2.5 cm and uniformly distributed charge q=4.5e-12 C. Take the electric potential at the sphere's center to be zero. What is V at radial distance r=2.2 cm?
A charge of q-+ 10.7 C is uniformly distributed on a spherical shell of radius 18 cm. (a) What is the magnitude of the electric field just outside and just inside the shell? kV/m (outside) kV/m (inside) (b) What is the magnitude of the electric potential just outside and just inside the shell? V (outside) V (inside) (c) What is the electric potential at the center of the shell? What is the electric field at that point? kV/m