Ratio of escape speeds from the surfaces of two uniformly uniformly dense planet of densities `rho` and `2 rho` respectively having equal radii is

Two spheres A and B of equal radii R, each are uniformly dense with densities 2 rho and rho respectively are placed as shown in figure.The initial acceleration of particle placed at point P due to gravity of both the spheres will be (P is just above the surface of sphere B).

A solid sphere having volume V and density rho floats at the interface of two immiscible liquids of densites rho_(1) and rho_(2) respectively. If rho_(1) lt rho lt rho_(2) , then the ratio of volume of the parts of the sphere in upper and lower liquid is

If two liquids of same mass but densities rho_1 and rho_2 respectively are mixed, then the density of the mixture is:

Pertaining to two planets, the ratio of escape velocities from respective surfaces is 1:2 , the ratio of the time period of the same simple pendulum at their respective surfaces is 2:1 (in same order). Then the ratio of their average densities is

Two non-conducting solid spheres of radii R and 2R, having uniform volume charge densities rho_1 and rho_2 respectively, touch each other. The net electric field at a distance 2R from the centre of the smaller sphere, along the line joining the centres of the spheres, is zero. The ratio rho_1/rho_2 can be

Find the relation between the gravitational field on the surface of two planets A and B of masses m_(A), m_(B) and radii R_(A) and R_(B), respectively if a. they have equal mass. b. they have equal (uniform)density.

The density of the core a planet is rho_(1) and that of the outer shell is rho_(2) . The radii of the core and that of the planet are R and 2R respectively. The acceleration due to gravity at the surface of the planet is same as at a depth R . Find the ratio of (rho_(1))/(rho_(2))

The density of the core a planet is rho_(1) and that of the outer shell is rho_(2) . The radii of the core and that of the planet are R and 2R respectively. The acceleration due to gravity at the surface of the planet is same as at a depth R . Find the ratio of (rho_(1))/(rho_(2))

The density of the core a planet is rho_(1) and that of the outer shell is rho_(2) . The radii of the core and that of the planet are R and 2R respectively. The acceleration due to gravity at the surface of the planet is same as at a depth R . Find the radio of (rho_(1))/(rho_(2))