A body is moving in a circular orbit. It is just about to slide to the outer side and `mu mg =(mv^(2))/l`. In this expression, `mu` represents

A body of mass m is moving in a circular orbit of radius R about a planet of mass M. At some instant, it splits into two equal masses. The first mass moves in a circular orbit of radius R/2 . And the other mass, in a circular orbit of radius (3R)/(2) . The difference between the final and initial total energies is :

A body is moving in a low circular orbit about a planet of mass M and radius R. The radius of the orbit can be taken to be R itself. Then the ratio of the speed of this body in the orbit to the escape velocity from the planet is :

The potential energy of a particle of mass ? at a distance ? from a fixed point ? is given by V(r)=kr^(2)//2 , where ? is a positive constant of appropriate dimensions. This particle is moving in a circular orbit of radius ? about the point ?. If ? is the speed of the particle and ? is the magnitude of its angular momentum about ?, which of the following statements is (are) true?

A star like the sun has serveral bodies moving around it at different distance. Consider that all of them are moving in circular orbits. Let r be the distance of the body from the centre of the star and let its linear velocity be upsilon , angular velocity omega , kinetic energy K , gravitational potential energy U , total energy E and angular momentum L . As the radius r of the orbit increase, determine which of the above quantities increase and which ones decrease.

An electron is in a circular orbit about the nucleus of an atom. Find the ratio between the orbital magnetic dipole moment vec mu and the angular momentum vec L of the electron about the center of its orbit.

A particle of charge -q and mass m moves in a circular orbit about a fixed charge +Q. Show that the r^(3) alpha T^(2) law, is satisfied, where r is the radius of orbit and T is time period.

A satellite of mass M is in a circular orbit of radius R about the centre of the earth. A meteorite of the same mass, falling towards the earth, collides with the satellite completely inelastically. The speeds of the satellite and the meteorite are the same, just before the collision. The subsequent motion of the combined body will be:

A satellite of mass M is in a circular orbit of radius R about the centre of the earth. A meteorite of the same mass, falling towards the earth, collides with the satellite completely inelastically. The speeds of the satellite and the meteorite are the same, just before the collision. The subsequent motion of the combined body will be:

A bob of mass m is attached at one end of a string of length l other end of the string is fixed at point O . Bob is rotating in a circular path of radius l in horizontal plane about O with constant speed v , as shown in the figure. The average force exterted by string on the bob during its :- (A) half revolution will be (mv^(2))/(pil) (B) half revolution will be (2mv^(2))/(pil) (C) one fourth revolution will be (sqrt2mv^(2))/(pil) (D) one revolution will be zero Select correct alternative :-

A car of mass m is moving on a level circular track of radius R if mu_(s) represents the static friction between the road and tyres of the car, the maximum speed of the car in circular motion is given by.