A massless string of length 1.2 m has a breaking strength of 2 kg wt . A stone of mass 0.4 kg tied to one end of the string is made to move in a vertical circle by holding the other end in hand . Can the particle describe the vertical circle ? Take `g = 10 ms^(-2)`.

A massless string of length 1.2 m, has a breaking strength of 2 kg wt. A stone of mass 0.4 kg, tied to one end of the string, is made to move in a vertical circle, by holding the other end in the hand. Can the particle describe the vertical circle? (Take g = 10 m s^-2 )

A massless, inextensible string of length 1 m has a breaking strength of 1 kg wt. A stone of mass 0.2 kg tied to one end of the string is made to move in a vertical circle. Can the stone describe the vertical circle? (g=10 ms^(-2))

A massless, inextensible string of length 1 m has a breaking strength of 1 kg wt. A stone of mass 0.2 kg tied to one end of the string is made to move in a vertical circel. Can te stone decribe the vertical circle? (g=10 ms^(-2))

A stone is tied to one end of a string and rotated in a vertical circle . What is the difference in tensions of the string at lowest and highest points of the vertical circle ?

A stone of mass 1 kg is tied to a string 2m long and it's rotated at constant speed of 40 ms^(-1) in a vertical circle. The ratio of the tension at the top and the bottom is [Take g=10m s^(2) ]

A stone of mas 1 kg is tied to one end of a string of length 0.5 m. It is whirled in a vertical circle. If the maximum tension in the string is 58.8 N, the velocity at the top is

A stone is attached to one end of a string and rotated in a vertical circle . If the string breaks at the position of maximum tension , then it will break at