The gravitational field strength `vecE` and gravitational potential `V` are releated as
`vecE=-((deltaV)/(deltax)hati+(deltaV)/(deltay)hatj+(deltaV)/(deltaz)hatk)`

In the figure, transversal lines represent equipotential surfaces. A particle of mass `m` is released from rest at the origin. The gravitational unit of potential , `1vecV=1cm^(2)//s^(2)`
Speed of the particle `(v)` (`y` is in cm and v in cm/s) as function of its `y`-co-ordinate is

The gravitational field strength vecE and gravitational potential V are releated as vecE=-((deltaV)/(deltax)hati+(deltaV)/(deltay)hatj+(deltaV)/(deltaz)hark) In the figure, transversal lines represent equipotential surfaces. A particle of mass m is released from rest at the origin. The gravitational unit of potential , 1vecV=1cm^(2)//s^(2) Speed of the particle (v) ( y is in cm and v is in cm//s) as function of its y-co ordinate is

The gravitational field strength vecE and gravitational potential V are releated as vecE=-((deltaV)/(deltax)hati+(deltaV)/(deltay)hatj+(deltaV)/(deltaz)hatk) In the figure, transversal lines represent equipotential surfaces. A particle of mass m is released from rest at the origin. The gravitational unit of potential , 1vecV=1cm^(2)//s^(2) x -component of the velocity of the particle at the point (4cm, 4cm) is

The gravitational field strength vecE and gravitational potential V are releated as vecE=-((deltaV)/(deltax)hati+(deltaV)/(deltay)hatj+(deltaV)/(deltaz)hatk) In the figure, transversal lines represent equipotential surfaces. A particle of mass m is released from rest at the origin. The gravitational unit of potential , 1vecV=1cm^(2)//s^(2) y -component of E a the point whose co-ordinates are (4cm,4cm) is

The gravitational field strength vecE and gravitational potential V are releated as vecE=-((deltaV)/(deltax)hati+(deltaV)/(deltay)hatj+(deltaV)/(deltaz)hatk) In the figure, transversal lines represent equipotential surfaces. A particle of mass m is released from rest at the origin. The gravitational unit of potential , 1vecV=1cm^(2)//s^(2) x -component of the velocity of the particle at the point (4cm,4cm) is

A particle of mass 1 kg is released from rest at a point where gravitational potential is 5 J/kg. After some time, it passes through a point B with a speed of 1 m/s. What is the gravitational potential at B ?

Two particles of mass m_(1) and m_(2) are approaching towards each other under their mutual gravitational field. If the speed of the particle is v, the speed of the center of mass of the system is equal to :

A particle of charge per unit mass alpha is released from origin with a velocity vecv=v_(0)hati uniform magnetic field vecB=-B_(0)hatk . If the particle passes through (0,y,0) , then y is equal to

We know that electric field (E ) at any point in space can be calculated using the relation vecE = - (deltaV)/(deltax)hati - (deltaV)/(deltay)hatj - (deltaV)/(deltaz)hatk if we know the variation of potential (V) at that point. Now let the electric potential in volt along the x-axis vary as V = 2x^2 , where x is in meter. Its variation is as shown in figure A charge particle of mass 10 mg and charge 2.5 muC is released from rest at x = 2 m . Find its velocity when it crosses origin.

We know that electric field (E ) at any point in space can be calculated using the relation vecE = - (deltaV)/(deltax)hati - (deltaV)/(deltay)hatj - (deltaV)/(deltaz)hatk if we know the variation of potential (V) at that point. Now let the electric potential in volt along the x-axis vary as V = 2x^2 , where x is in meter. Its variation is as shown in figure Draw the variation of electric field (E ) along the x-axis.

Two point masses m and 2m are kept at points A and B as shown. E represents magnitude of gravitational field strength and V the gravitational potential. As we move from A to B