Particles `P` and `Q` of masses `20g` and `40g`, respectively, are projected from positions `A` and `B` on the ground. The initial velocities of `P` and `Q` make angles of `45^(circ)` and `135^(circ)`, respectively with the horizontal as shown in the fig. Each particle has an initial speed of `49m//s`. The separation `AB` is `245m`. Both particles travel in the same vertical plane and undergo a collision. After the collision `P` retraces its path. The separation of `Q` from its initial position when it hits the ground is A. `245m`B. `(245)/(3)m`C. `(245)/(2)m`D. `(245)/(sqrt(2))m`

Particles `P` and `Q` of masses `20g` and `40g`, respectively, are pro

1.	Particles `P` and `Q` of masses `20g` and `40g`, respectively, are projected from positions `A` and `B` on the ground. The initial velocities of `P` and `Q` make angles of `45^(circ)` and `135^(circ)`, respectively with the horizontal as shown in the fig. Each particle has an initial speed of `49m//s`. The separation `AB` is `245m`. Both particles travel in the same vertical plane and undergo a collision. After the collision `P` retraces its path. The separation of `Q` from its initial position when it hits the ground is A. `245m`B. `(245)/(3)m`C. `(245)/(2)m`D. `(245)/(sqrt(2))m`
Answer» Correct Answer - C Both the particles will collide at the highest point of their path. Momentum of the particle `P` just before collision `m_(A)V_(A) cos 45^("circ") = 20 xx 10^(-3) xx 49 xx (1)/(sqrt(2))` `(980)/(sqrt(2)) xx 10^(-3)kg m//s` Momentum of particle `Q` just before collision is `m_(B)V_(B) cos 135^("circ") = -40 xx 10^(-3) xx 49 xx (1)/(sqrt(2)) = (1960)/(sqrt(2)) xx 10^(-3) kg m//s` After collision, let velocity of `Q` be `V` and velocity of `P` be `49 cos 45^("circ")`. Therefore, momentum after collision is `40 xx 10^(-3)V - (49 xx 20 xx 10^(3))/(sqrt(2))` Applying law of conservation of momentum `(980)/(sqrt(2)) xx 10^(-3) - 1960 xx (10^(-3))/(sqrt(2)) = 40 xx 10^(-3)V-(980 xx 10^(-3))/(sqrt(2))` or `v = 0` Thus, particle `Q` will fall freely after collision. So, the distance travelled by it will be `245//2m`. i.e., `122.5m`

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