Directions: On this worksheet you will be investigating the relationships between momentum and energy.

Question 1 If F_{max} = 17 N and F_{min} = -11 N then calculate the impulse delivered to a 3-kg mass during the 5 seconds graphed above.

33.5 N sec44.5 N sec1 N sec0.5 N sec-10.5 N sec

Question 2 If the object's initial velocity in Question 1 was 6.6 m/sec, what will be its final velocity at the end of these 5 seconds?

-6.4 m/sec20.3 m/sec6.8 m/sec3.1 m/sec2.4 m/sec

Question 3 What was the magnitude of the average force acting on the 3-kg mass in Question 1 during the 5 seconds displayed on the graph?

-2.1 N2.5 N3 N6.7 N0.1 N

Question 4 A 6.6-gram bullet moving at 260 m/sec travels through a block of wood and emerges out the other side moving at 230 m/sec. If it takes 28 µsecs (1 µsec = 1 x 10^{-6} seconds) for the bullet to bore through the wood, what average force did the wood exert on the bullet?

6.13 x 10^{4} N1.16 x 10^{6} N5.42 x 10^{4} N-7.07 x 10^{3} N

Question 5 During target practice, a man shoots a 6.6-gram bullet with a horizontal velocity of 230 m/sec at a 1.5-kg wooden block balanced on the top of a 1.1-meter tall fence post. If the bullet embeds in the block, how fast will the block-bullet be knocked off the post?

153.33 m/sec1.01 m/sec0.043 m/sec228.99 m/sec

Question 6 After being knocked off, how far from the base of the fence post will the block in Question 5 hit the ground?

1.08 m0.34 m0.23 m0.77 m0.48 m

Question 7 A second 6.6-gram bullet is fired at another 1.5-kg block which is initially at rest on a table. The bullet embeds in the block resulting in the block sliding 180 centimeters before coming to a stop. The coefficient of friction between the block and the table's surface is µ = 0.382.How much work will the friction between the table and block do on the block while bringing it to a stop?

3.1 J10.2 J5.6 J68.8 J26.6 J

Question 8 How fast was the original bullet in Question 7 travelling before it struck the block?

510 m/sec451.6 m/sec840 m/sec368 m/sec238 m/sec

Question 9 As shown in the diagrams provided below, a ball of mass 1 kg is originally moving along the x-axis with a velocity of 11 m/sec towards the origin. As it approaches the origin, it delivers a glancing blow to a stationary 2-kg mass. After the collision, the 1-kg ball continues traveling towards the left, into the second quadrant, at a reduced speed of 5 m/sec at an angle of 37º above the negative x-axis.

What is the final momentum of the 2-kg mass after the collision?

5.5 kg m/sec3 kg m/sec7.6 kg m/sec7 kg m/sec15.2 kg m/sec

Question 10 Within the system, what fraction of the 1-kg ball's original KE remains after the collision?