Which graph best represents the variation of electric potential as a function of distance from the centre of a uniformly charged solid sphere of charge of radius R ?

Flux (ph) as a function of distance (r) from centre of uniformly charged solid sphere of charge Q and radius R , is best represented by

Which one of the following graphs represents the variation of electric field with distance r from the centre of a charged spherical conductor of radius R?

A non-conducting solid sphere of radius R, has a uniform charge density. The graph representing variation of magnitude of electric field (E) as a function of distance (x) from the centre of the sphere is

Graph shows magnitude of electric field (E) , charge enclosed (q_("enclosed:)) within the concentic sphere and net flux (phi) through a concentric spherical Gaussian surface as a function of distance (r) from centre of a uniformly positive charged solid sphere of radius R. Choose the correct option (s):

Find the electric potential energy of a uniformly charged sphere.

Potential at a point x-distance from the centre inside the conducting sphere of radius R and charged with charge Q is

Draw a plot showing variation of electric field with distance from the centre of a solid conducting sphere of radius R, having of + Q on its surface.

A solid sphere of radius R is charged uniformly. The electrostatic potential V is plotted as a function of distance r from the centre of th sphere. Which of the following best represents the resulting curve?

The electrostatic potential of a uniformly charged thin spherical shell of charge Q and radius R at a distance r from the centre

Find the electric field at the centre of a uniformly charged semicircular ring of radius R. Linear charge density is lamda