* (4) A billiard ball moving at 10m/s along the +ve x - axis collides elastically with a second billiarball at rest. The balls have the same masses. After the collision, the incoming ball moves off at anangle of 37°, to the original direction of motion, and the second ball deflects at an angle 02 to thesame axis. Find the speeds of the two balls after collision and the angle 02* (5)Consider a 4kg & 6kg blocks are sliding down an inclined plane whose inclination. from the horizontal is 370 .The blocks are in contact but are not fastened together asshown in figure- 1. (use sin370 = 0.6, Cos370 = 0.8 andg = 10m/s2)Federal DemocraticMinistry of EducaticM1= 4kgH1 = 0.2Find : (a) the contact force b/n mss-1 & 2 M2= 6kg(b)the acceleration the system.H2 = 0.4370nhoun in Fíaure - 2. in order

As per our guidelines, I can solve only the first question. Hence as per the first question, the…

* (4) A billiard ball moving at 10m/s along the +ve x - axis collides elastically ball at rest. The balls have the same masses. After the collision, the incoming ball moves off at an angle of 37°, to the original direction of motion, and the second ball deflects at an angle 02 to the same axis. Find the speeds of the two balls after collision and the angle 0,. * (5)Consider a 4kg & 6kg blocks are sliding down an inclined plane whose inclination from the horizontal is 37° .The blocks are in contact but are not fastened together as shown in figure - 1. (use sin370 = 0.6, Cos370 = 0.8 and g = 10m/s2) M1= 4kg H1 = 0.2 Find : (a) the contact force b/n mss-1 & 2 M2= 6kg (b)the acceleration the system. H2 = 0.4 370

* (4) A billiard ball moving at 10m/s along the +ve x - axis collides elastically ball at rest. The balls have the same masses. After the collision, the incoming ball moves off at an angle of 37°, to the original direction of motion, and the second ball deflects at an angle 02 to the same axis. Find the speeds of the two balls after collision and the angle 0,. * (5)Consider a 4kg & 6kg blocks are sliding down an inclined plane whose inclination from the horizontal is 37° .The blocks are in contact but are not fastened together as shown in figure - 1. (use sin370 = 0.6, Cos370 = 0.8 and g = 10m/s2) M1= 4kg H1 = 0.2 Find : (a) the contact force b/n mss-1 & 2 M2= 6kg (b)the acceleration the system. H2 = 0.4 370

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter9: Linear Momentum And Collisions

Section: Chapter Questions

Problem 9.91AP: A 2.00-g particle moving at 8.00 m/s makes a perfectly elastic head-on collision with a resting...

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