A small body of mass m slides without friction from the top of a hemisphere of radius r. At what hight will the body be detached from the surface of hemisphere?

A particle of mass m is placed in equilibrium at the top of a fixed rough hemisphere of radius R. Now the particle leaves the contact with the surface of the hemisphere at angular position theta with the vertical where cos theta"="(3)/(5). if the work done against friction is (2mgR)/(10x), find x.

Determine the centre of mass of a uniform hemisphere of radius R.

A chain of length l and mass m lies of the surface of a smooth hemisphere of radius Rgtl with one end tied to the top of the hemisphere. Taking base of the hemisphere as reference line, find the gravitational potential energy of the chain.

A charge 'Q' is placed at the centre of a hemispherical surface of radius 'R'. The flux of electric field due to charge 'Q' through the surface of hemisphere is

A body of mass m is placed at the centre of the spherical shell of radius R and mass M. The gravitation potential on the surface of the shell is

A small block of mass m projected horizontally from the top of the smooth and fixed hemisphere of radius r with speed u as shown. For values of u ge u_(0)(u_(0)=sqrt(gr)) it does not slide on the hemisphere. l i.e., leaves the surface at the top itself. For u=u_(0)//3 , Find the height from the ground at which it leaves the hemisphere

A small block of mass m has speed sqrt(gR) /2 at the top most point of a fixed hemisphere of radius R as shown in figure. The angle theta , when block loses the contact with the hemisphere is

A small block of mass m projected horizontally from the top of the smooth and fixed hemisphere of radius r with speed u as shown. For values of u ge u_(0)(u_(0)=sqrt(gr)) it does not slide on the hemisphere. l i.e., leaves the surface at the top itself. In the above problem find its net acceleration at the instant it levels the hemisphere.

A small block of mass m projected horizontally from the top of the smooth and fixed hemisphere of radius r with speed u as shown. For values of u ge u_(0)(u_(0)=sqrt(gr)) it does not slide on the hemisphere. l i.e., leaves the surface at the top itself. For u=2 u_(0) , it lands at point P on ground. Find OP.

A small steel sphere of mass m and radius r rolls without slipping on the fiictionless surface of a large hemisphere of radius R {R gt gt r) whose axis of symmetry is vertical. It starts at the top from the rest, (a) What is the kinetic energy at the bottom ? (b) What fraction is the rotational kinetic energy of the total kinetic energy ? (c) What fraction is the rotational kinetic energy of the total kinetic energy? (d) What fraction is the translational kinetic energy of the total kinetic energy?