Object A has mass mA = 8 kg and initial momentum vector pA, i = < 22, -8, 0 > kg · m/s, just before it strikes object B, which has mass mB = 12 kg. Just before the collision object B has initial momentum vector pB, i = < 3, 5, 0 > kg · m/s.

1)Consider a system consisting of both objects A and B. What is the total initial momentum of this system, just before the collision? vector psys, i = ? kg · m/s

2) The forces that A and B exert on each other are very large but last for a very short time. If we choose a time interval from just before to just after the collision, what is the approximate value of the impulse applied to the two-object system due to forces exerted on the system by objects outside the system? vector FnetΔt = ? N · s

3) Therefore, what does the momentum principle predict that the total final momentum of the system will be, just after the collision? vector sys, f = ? kg · m/s

4) Just after the collision, object A is observed to have momentum vector pA, f = < 19, 5, 0 > kg · m/s. What is the momentum of object B just after the collision? vector pB, f = ? kg · m/s At this point we've learned all that we can from applying the momentum principle. Next we'll see what additional information we can obtain by using the energy principle.

5) Before the collision, what was the magnitude of the momentum of object A? |vector pA, i| = ? kg · m/s

6) Before the collision, what was the kinetic energy of object A? Remember that you can calculate kinetic energy not only from K = (1/2)m|vector v|2 but more directly from K = (1/2)|vector p|2/m. KA, i = ? J

7) Before the collision, what was the magnitude of the momentum of object B? |vector pB, i| = ? kg · m/s

8) Before the collision, what was the kinetic energy of object B? KB, i = ? J

9) After the collision, what was the magnitude of the momentum of object A? |vector pA, f| = ? kg · m/s

10) After the collision, what was the kinetic energy of object A? KA, f = ? J

11) After the collision, what was the magnitude of the momentum of object B? |vector pB, f| = ? kg · m/s

12) After the collision, what was the kinetic energy of object B? KB, f = ? J

13) Before the collision, what was the total kinetic energy of the system? Ksys, i = KA, i + KB, i = ? J

14) After the collision, what was the total kinetic energy of the system? Ksys, f = KA, f + KB, f = ? J

15) What kind of collision was this? (Remember that an "elastic" collision is one where the final value of the total kinetic energy is equal to the initial value of the total kinetic energy.)

A not enough information to decide

B inelastic

C elastic

16) Assume that all of the energy is either kinetic energy or thermal energy. Calculate the increase of thermal energy of the two objects. ΔEA, thermal + ΔEB, thermal = ? J