(B) 300 J(C)50 J(D) 125 J4) Consider an 80 kg man and 320 kg horse both running along a road with the same kinetic energy.The man must run(A) with the same speed as the horse.(CSS) 4 times as fast as the horse.(B) twice as fast as the horse.(D) 16 times as fast as the horse.5)particle A is travelling at a velocity of []m/s. It collides with particle B which has a velocity of10[Jm/s. The particle move together. The mass of particle A is 2kg and the mass of particle B is 3kg.8Find the velocity of the combined particles after the collision.8.(B) []m/s42,2050(A) [ ]m/s(C) Im/s(D) [_16Im/s46)Which of the following is NOT true about conservation of linear momentum.(A)The impulse becomes to zero.(C)The total momentum is constant.(B)The change in momentum is constant.(D)The change in momentum is zero7)Two billiard balls of equal mass undergo a perfectly elastic head- on collision. If the speed of one ballwas initially 2.00m/s, and of the other 3.00m/s in the opposite direction, what will be their speedsVi & V2 after the collision respectively?(A)2m/s &- 3m/s(B) -3m/s & 2m/s(C)2m/s & 3m/s(D)-3m/s &-2m/sBy Yishak PaulosDate of Submission : 26/08/2013E.C"To t

Name: (B) 300 J(C)50 J(D) 125 J4) Consider an 80 kg man and 320 kg horse bo
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Description: (B) 300 J(C)50 J(D) 125 J4) Consider an 80 kg man and 320 kg horse both running along a road with the same kinetic energy.The man must run(A) with the same speed as the horse.(CSS) 4 times as fast as the horse.(B) twice as fast as the horse.(D) 16 t

4) given data , m = 80kg and M =320 kg. 5) mA= 2 kg and mB = 3 , VA = (5 2) and vB = (10 8) 6) we…

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4) Consider an 80 kg man and 320 kg horse both running along a road with the same kinetic energy. The man must run (A) with the same speed as the horse. (CSS) 4 times as fast as the horse. (B) twice as fast as the horse. (D) 16 times as fast as the horse. 5)particle A is travelling at a velocity of []m/s. It collides with particle B which has a velocity of -2 Jm/s. The particle move together. The mass of particle A is 2kg and the mass of particle B is 3kg. 8. Find the velocity of the combined particles after the collision. 8 8.4. 42. (B) Im/s 50 (A) [ ]m/s (C) m/s (D)[ 16m/s 4 20 6)Which of the following is NOT true about conservation of linear momentum. (A)The impulse becomes to zero. (C)The total momentum is constant. (B)The change in momentum is constant. (D)The change in momentum is zero _7)Two billiard balls of equal mass undergo a perfectly elastic head - on collision. If the speed of one ball was initially 2.00m/s, and of the other 3.00m/s in the opposite direction, what will be their speeds V1 & V2 after the collision respectively? (A)2m/s & - 3m/s (B) -3m/s & 2m/s (C)2m/s & 3m/s (D)-3m/s & -2m/s

4) Consider an 80 kg man and 320 kg horse both running along a road with the same kinetic energy. The man must run (A) with the same speed as the horse. (CSS) 4 times as fast as the horse. (B) twice as fast as the horse. (D) 16 times as fast as the horse. 5)particle A is travelling at a velocity of []m/s. It collides with particle B which has a velocity of -2 Jm/s. The particle move together. The mass of particle A is 2kg and the mass of particle B is 3kg. 8. Find the velocity of the combined particles after the collision. 8 8.4. 42. (B) Im/s 50 (A) [ ]m/s (C) m/s (D)[ 16m/s 4 20 6)Which of the following is NOT true about conservation of linear momentum. (A)The impulse becomes to zero. (C)The total momentum is constant. (B)The change in momentum is constant. (D)The change in momentum is zero _7)Two billiard balls of equal mass undergo a perfectly elastic head - on collision. If the speed of one ball was initially 2.00m/s, and of the other 3.00m/s in the opposite direction, what will be their speeds V1 & V2 after the collision respectively? (A)2m/s & - 3m/s (B) -3m/s & 2m/s (C)2m/s & 3m/s (D)-3m/s & -2m/s

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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