Figure shows two shells of masses `m_(1)` and `m_(2)`. The shells are concentric. At which point, a particle of mass `m` shall experience zero force?

The figure shows a spherical shell of mass M . The point A is not at the centre but away from the centre of the shell. If a particle of mass m is placed at A , then

Figure shows a hemispherical shell of mass M and radius R and a concentric shell of mass m and radius 3R/4.

In the figure given below, two particles of masses m and 2m are fixed in place on an axis. Where on the axis can a third particle of mass 3m be placed (other than at infinity) so that the gravitational force on it from the first two particles is zero?

Two block of masses m_(1) and m_(2) are connected as shown in the figure. The acceleration of the block m_(2) is:

Two concentric shells of masses M_(1) and M_(2) are concentric as shown. Calculate the gravitational force on m due to M_(1) at points P,Q and R .

Two concentric shells of uniform density of mass M_(1) and M_(2) are situated. The forces experienced by a particle of mass m when palced at positions A,B and C respectively are given OA =p,OB = q and OC =r . .

Two spherical shells have masses m and 2m as shows. Choose the correct options.

Two concentric spherical shells have masses M_1,M_2 and radii R_1,R_2(R_1ltR_2) . What is the force exerted by this system on a particle of mass m if it is placed at a distance (R_1+R_2)/2 from the center?

Two stationary particles of masses M_(1) and M_(2) are 'd' distance apart. A third particle lying on the line joining the particles, experiences no resultant gravitational force. What is the distance of this particle from M_(1) ?

Consider a system of two particles having masses m_(1) and m_(2) . If the particle of mass m_(1) is pushed towards the centre of mass of particles through a distance d , by what distance would the particle of mass m_(2) move so as to keep the mass centre of particles at the original position?