`v_(e)=sqrt((2GM)/(R))`

Given that v=sqrt((2GM)/(R )) . Find log v.

Check the dimensional consistency of the following equations : (i) de-Broglie wavelength , lambda=(h)/(mv) (ii) Escape velocity , v=sqrt((2GM)/(R)) .

If mass of earth is M ,radius is R and gravitational constant is G,then work done to take 1kg mass from earth surface to infinity will be (A) sqrt((GM)/(2R)) (B) (GM)/(R)] (C) sqrt((2GM)/(R))]

Match the column : A particle at a distance r from the centre of a uniform spherical planet of mass M radius R(lt r) has a velocity v magnitude of which is given in column I. Match trajectory from column II about possible nature of orbit. {:(,"Column I",,"Column II"),((A),0lt V lt sqrt((GM)/(r )),(P),"Straight line"),((B),sqrt((GM)/(r )),(Q),"Circle"),((C ),sqrt((2GM)/(r )),(R ),"Parabola"),((D),v gt sqrt((2GM)/(r )),(S ),"Ellipse"):}

The initial velocity v_(i) required to project a body vertically upward from the surface of the earth to reach a height of 10R, where R is the radius of the earth, may be described in terms of escape velocity v_(e ) such that v_(i)= sqrt((x)/(y)) xx v_(e ) . The value of x will be __________ .

Chack the correctness of the relations. (i) escape velocity, upsilon = sqrt((2GM)/(R )) (ii) v =(1)/(2l) sqrt((T)/(m)) , where l is length, T is tension and m is mass per unit length of the string.

Match the items in column I to the items in column II given below : G = universal gravitational constant, M = mass of earth, R = radius of earth {:(,"Column -I",,"Column -II"),((A),"Escape velocity from a height R above earth's surface",(p),sqrt((4GM)/(R ))),((B),"Minimum horizontal velocity required for a particle at a height R above earth's surface to avoid falling on earth",(q),sqrt((GM)/(R ))),((C ),"Escape valocity on the surface of earth if earth's diameter were shrunk to half of its present value",(r ),sqrt((GM)/(3R))),((D),"Velocity of a body thrown from the earth's surface to reach a height of " (R )/(3) " from the surface of the earth",(s),sqrt((GM)/(2R))):}

Two particles of equal masses m go round a circle of radius R under the action of their mutual gravitational attraction. The speed of each particle is v=sqrt((Gm)/(nR)) . Find the value of n.