If `E , M , J , and G` , respectively , denote energy , mass , angular momentum , and gravitational constant , then `EJ^(2) //M^(5) G^(2)` has the dimensions of

If E, M, L and G denote energy, mass, angular momentum and gravitational constant repectively then the quantity (E^(2)L^(2)//M^(5)G^(2)) has the dimensions of :-

In the expression P =E L^2 m^(-5) G^(-2), E, m, L and G denote energy, mass, angular momentum and gravitational constant, respectively. Show that P is a dimensionless quantity.

If J is the angular momentum and E is the kinetic energy, then (J^2)/E has the dimensions of

h d G has the dimensions of (h = height , d = density , G = Gravitational constant)

If E = energy , G = gravitational constant, I =impulse and M =mass, then dimensions of (GIM^(2))/(E^(2) are same as that of

The escape velocity of a sphere of mass m is given by (G= univesal gravitational constant, M_(e) = mass of the earth and R_(e) = radius of the earth)

Kepler's third law states that square of period revolution (T) of a planet around the sun is proportional to third power of average distance i between sun and planet i.e. T^(2)=Kr^(3) here K is constant if the mass of sun and planet are M and m respectively then as per Newton's law of gravitational the force of alteaction between them is F=(GMm)/(r^(2)) , here G is gravitational constant. The relation between G and K is described as

A planet of mass M, has two natural satellites with masses m1 and m2. The radii of their circular orbits are R_(1) and R_(2) respectively. Ignore the gravitational force between the satellites. Define v_(1), L_(1), K_(1) and T_(1) to be, respectively, the orbital speed, angular momentum, kinetic energy and time period of revolution of satellite 1 , and v_(2), L_(2), K_(2) and T_(2) to be he corresponding quantities of satellite 2. Given m_(1)//m_(2) = 2 and R_(1)//R_(2) = 1//4 , match the ratios in List-I to the numbers in List-II.

The acceleration due to gravity at a piece depends on the mass of the earth M, radius of the earth R and the gravitational constant G. Derive an expression for g?

The relation between angular momentum J of a body and rotational kinetic energy is given by J=sqrt(2EI) . The graph between J and sqrt(E) will be: