A particle P is sliding down a frictionless hemispherical bowl. It passes the point A at `t=0`. At this instant of time, the horizontal component of its velocity is v. A bead Q of the same mass as P is ejected from A at `t=0` along the horizontal string AB, with the speed v. Friction between the bead and the string may be neglected. Let `t_P` and `t_Q` be the respective times taken by P and Q to reach the point B. Then: A. `t_(P)ltt_(Q)`B. `t_(P)=t_(Q)`C. `t_(P)gt t_(Q)`D. `(t_(P))/(t_(Q))=("length of arc ACB")/("length of chord AB")`

A particle P is sliding down a frictionless hemispherical bowl. It pas

1.	A particle P is sliding down a frictionless hemispherical bowl. It passes the point A at `t=0`. At this instant of time, the horizontal component of its velocity is v. A bead Q of the same mass as P is ejected from A at `t=0` along the horizontal string AB, with the speed v. Friction between the bead and the string may be neglected. Let `t_P` and `t_Q` be the respective times taken by P and Q to reach the point B. Then: A. `t_(P)ltt_(Q)`B. `t_(P)=t_(Q)`C. `t_(P)gt t_(Q)`D. `(t_(P))/(t_(Q))=("length of arc ACB")/("length of chord AB")`
Answer» Correct Answer - A P particle has `a_(1)=g sin theta` due to which its horizontal component of velocity gt v

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