F a1a1 m1m1 F m2m2 m1m1 a3a3 1) 3/4 a 1 2) 3/2 a 1 3) 1/2 a 1 4) 4/3 a 1 5) 2/3 a 1 A force F acts on mass m 1 giving acceleration a 1. The same force.

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F a1a1 m1m1 F m2m2 m1m1 a3a3 1) 3/4 a 1 2) 3/2 a 1 3) 1/2 a 1 4) 4/3 a 1 5) 2/3 a 1 A force F acts on mass m 1 giving acceleration a 1. The same force acts on a different mass m 2 giving acceleration a 2 = 2a 1. If m 1 and m 2 are glued together and the same force F acts on this combination, what is the resulting acceleration? F a 2 = 2a 1 m2m2 ConcepTest 4.6 Force and Two Masses

m 2 (1/2)m 1 2a 1 (3/2)m 1 (2/3)a 1 same applied force. Mass m 2 must be (1/2)m 1 because its acceleration was 2a 1 with the same force. Adding the two masses together gives (3/2)m 1, leading to an acceleration of (2/3)a 1 for the same applied force. F = m 1 a 1 F a1a1 m1m1 F m2m2 m1m1 a3a3 F = (3/2)m 1 a 3 => a 3 = (2/3) a 1 1) 3/4 a 1 2) 3/2 a 1 3) 1/2 a 1 4) 4/3 a 1 5) 2/3 a 1 A force F acts on mass m 1 giving acceleration a 1. The same force acts on a different mass m 2 giving acceleration a 2 = 2a 1. If m 1 and m 2 are glued together and the same force F acts on this combination, what is the resulting acceleration? F a 2 = 2a 1 m2m2 F = m 2 a 2 = (1/2 m 1 )(2a 1 ) ConcepTest 4.6 Force and Two Masses

ConcepTest 4.7 Climbing the Rope When you climb up a rope, the first thing you do is pull down on the rope. How do you manage to go up the rope by doing that?? 1) this slows your initial velocity which is already upward 2) you don’t go up, you’re too heavy 3) you’re not really pulling down – it just seems that way 4) the rope actually pulls you up 5) you are pulling the ceiling down

When you pull down on the rope, the rope pulls up on you!! reaction rope on youyou exerted on the rope When you pull down on the rope, the rope pulls up on you!! It is actually this upward force by the rope that makes you move up! This is the “reaction” force (by the rope on you) to the force that you exerted on the rope. And voilá, this is Newton’s 3 rd Law. ConcepTest 4.7 Climbing the Rope When you climb up a rope, the first thing you do is pull down on the rope. How do you manage to go up the rope by doing that?? 1) this slows your initial velocity which is already upward 2) you don’t go up, you’re too heavy 3) you’re not really pulling down – it just seems that way 4) the rope actually pulls you up 5) you are pulling the ceiling down

F F 12 F F 21 1) 1) The bowling ball exerts a greater force on the ping-pong ball 2) 2) The ping-pong ball exerts a greater force on the bowling ball 3) 3) The forces are equal 4) 4) The forces are zero because they cancel out 5) There are actually no forces at all ConcepTest 4.8a Bowling vs. Ping-Pong I In outer space, a bowling ball and a ping-pong ball attract each other due to gravitational forces. How do the magnitudes of these attractive forces compare?

F F 12 F F 21 forces The forces are equal and opposite by Newton’s 3 rd Law! 1) 1) The bowling ball exerts a greater force on the ping-pong ball 2) 2) The ping-pong ball exerts a greater force on the bowling ball 3) 3) The forces are equal 4) 4) The forces are zero because they cancel out 5) There are actually no forces at all ConcepTest 4.8a Bowling vs. Ping-Pong I In outer space, a bowling ball and a ping-pong ball attract each other due to gravitational forces. How do the magnitudes of these attractive forces compare?

ConcepTest 4.10a Contact Force I If you push with force F on either the heavy box (m 1 ) or the light box (m 2 ), in which of the two cases below is the contact force between the two boxes larger? 1) case A 2) case B 3) same in both cases F m2m2m2m2 m1m1m1m1A F m2m2m2m2 m1m1m1m1B

ConcepTest 4.10a Contact Force I only m 1 is the larger masslarger contact force The acceleration of both masses together is the same in either case. But the contact force is the only force that accelerates m 1 in case A (or m 2 in case B). Since m 1 is the larger mass, it requires the larger contact force to achieve the same acceleration. If you push with force F on either the heavy box (m 1 ) or the light box (m 2 ), in which of the two cases below is the contact force between the two boxes larger? 1) case A 2) case B 3) same in both cases F m2m2m2m2 m1m1m1m1A F m2m2m2m2 m1m1m1m1B Follow-up: What is the accel. of each mass?

1) 0 N 2) 50 N 3) 100 N 4) 150 N 5) 200 N Two tug-of-war opponents each pull with a force of 100 N on opposite ends of a rope. What is the tension in the rope? ConcepTest 5.3b Tension II

literally The tension is not 200 N !! 100 N This is literally the identical situation to the previous question. The tension is not 200 N !! Whether the other end of the rope is pulled by a person, or pulled by a tree, the tension in the rope is still 100 N !! 1) 0 N 2) 50 N 3) 100 N 4) 150 N 5) 200 N Two tug-of-war opponents each pull with a force of 100 N on opposite ends of a rope. What is the tension in the rope? ConcepTest 5.3b Tension II

ConcepTest 5.4 Three Blocks T3T3 T2T2 T1T1 3m 2m m a 1) T 1 > T 2 > T 3 2) T 1 < T 2 < T 3 3) T 1 = T 2 = T 3 4) all tensions are zero 5) tensions are random Three blocks of mass 3m, 2m, and m are connected by strings and pulled with constant acceleration a. What is the relationship between the tension in each of the strings?

T 1 wholeset largest T 1 pulls the whole set of blocks along, so it must be the largest. T 2 pulls the last two masses, but T 3 only pulls the last mass. ConcepTest 5.4 Three Blocks T3T3 T2T2 T1T1 3m 2m m a 1) T 1 > T 2 > T 3 2) T 1 < T 2 < T 3 3) T 1 = T 2 = T 3 4) all tensions are zero 5) tensions are random Three blocks of mass 3m, 2m, and m are connected by strings and pulled with constant acceleration a. What is the relationship between the tension in each of the strings? Follow-up: What is T 1 in terms of m and a?

ConcepTest 5.5 Over the Edge m 10kg a m a F = 98 N Case (1) Case (2) 1) case 1 2) acceleration is zero 3) both cases are the same 4) depends on value of m 5) case 2 In which case does block m experience a larger acceleration? In (1) there is a 10 kg mass hanging from a rope and falling. In (2) a hand is providing a constant downward force of 98 N. Assume massless ropes.

less accelerating down In (2) the tension is 98 N due to the hand. In (1) the tension is less than 98 N because the block is accelerating down. Only if the block were at rest would the tension be equal to 98 N. ConcepTest 5.5 Over the Edge m 10kg a m a F = 98 N Case (1) Case (2) 1) case 1 2) acceleration is zero 3) both cases are the same 4) depends on value of m 5) case 2 In which case does block m experience a larger acceleration? In (1) there is a 10 kg mass hanging from a rope and falling. In (2) a hand is providing a constant downward force of 98 N. Assume massless ropes.

ConcepTest 5.12 Will it Budge? 1) moves to the left 2) moves to the right 3) moves up 4) moves down 5) the box does not move A box of weight 100 N is at rest on a floor where m s = 0.5. A rope is attached to the box and pulled horizontally with tension T = 30 N. Which way does the box move? T m Static friction (  s  = 0.4  )

maximumm s N = 40 N 30 N The static friction force has a maximum of m s N = 40 N. The tension in the rope is only 30 N. So the pulling force is not big enough to overcome friction. ConcepTest 5.12 Will it Budge? 1) moves to the left 2) moves to the right 3) moves up 4) moves down 5) the box does not move A box of weight 100 N is at rest on a floor where  s = 0.4. A rope is attached to the box and pulled horizontally with tension T = 30 N. Which way does the box move? T m Static friction (  s  = 0.4  ) Follow-up: What happens if the tension is 35 N? What about 45 N?

R v top 1) F c = T – mg 2) F c = T + N – mg 3) F c = T + mg 4) F c = T 5) F c = mg You swing a ball at the end of string in a vertical circle. Since the ball is in circular motion there has to be a centripetal force. At the top of the ball’s path, what is F c equal to? ConcepTest 5.19c Going in Circles III

R v T gmggmg You swing a ball at the end of string in a vertical circle. Since the ball is in circular motion there has to be a centripetal force. At the top of the ball’s path, what is F c equal to? F c points toward the center of the circle, i.e. downward in this case. weight vectordown tension down F c = T + mg F c points toward the center of the circle, i.e. downward in this case. The weight vector points down and the tension (exerted by the string) also points down. The magnitude of the net force, therefore, is: F c = T + mg ConcepTest 5.19c Going in Circles III Follow-up: What is F c at the bottom of the ball’s path? 1) F c = T – mg 2) F c = T + N – mg 3) F c = T + mg 4) F c = T 5) F c = mg