A solid ball of radius R has a charge density `rho` given by `rho = rho_(0)(1-(r )/(R )) for 0le r le R` The electric field outside the ball is :

Consider a solid sphere oF radius R and mass density rho(r)=rho_(0)(1-(r^(2))/(R^(2))) 0 lt r le R . The minimum density oF a liquid in which it will Float is:

A ball of radius R carries a positive charges whose volume density at a point is given as rho=rho_(0)(1-r//R) , Where rho_(0) is a constant and r is the distance of the point from the center. Assume the permittivities of the ball and the enviroment to be equal to unity. (a) Find the magnitude of the electric field strength as a function of the distance r both inside and outside the ball. (b) Find the maximum intensity E_("max") and the corresponding distance r_(m) .

The current density is a solid cylindrical wire a radius R, as a function of radial distance r is given by J(r )=J_(0)(1-(r )/(R )) . The total current in the radial regon r = 0 to r=(R )/(4) will be :

A solid sphere of radius R_(1) and volume charge density rho = (rho_(0))/(r ) is enclosed by a hollow sphere of radius R_(2) with negative surface charge density sigma , such that the total charge in the system is zero . rho_(0) is positive constant and r is the distance from the centre of the sphere . The ratio R_(2)//R_(1) is

A solid non-conduction cylinder of radius R is charge such that volume charge density is proporation to r where r is distance from axis. The electric field E at a distance r(r lt R) well depend on r as.

A sphere of radius R has a variable charge density rho(r)=rho_(0)r^(n-1)(rleR) . If ratio of "potential at centre" and "potential at surface" be 3//2 then find the value of n

An infinitely long solid cylinder of radius R has a uniform volume charge density rho . It has a spherical cavity of radius R//2 with its centre on the axis of cylinder, as shown in the figure. The magnitude of the electric field at the point P , which is at a distance 2 R form the axis of the cylinder, is given by the expression ( 23 r R)/( 16 k e_0) . The value of k is . .

The mass density of a planet of radius R varie with the distance r form its centre as rho (r) = p_(0) ( 1 - (r^(2))/(R^(2))) . Then the graviational field is maximum at :

The diagram shows a uniformly charged bemisphere of radius R. It has volume charge density rho . If the electric field at a point 2R distance below its centre ?

Figure shows a uniformly charged hemisphere of radius R. It has a volume charge density rho . If the electric field at a point 2R, above the its center is E, then what is the electric field at the point 2R below its center?