Table 11.5: Totally Inelastic Collision Between Two Moving Carts of Unequal Mass (Velcro) Object Net Mass (kg) Color of Cart (m/s) (kg -m/s) (m/s) (kg - m/s) GREEN Gray 0.76 K9F0,440lm-0.310 -o.153 -0.116 0.2b ka0.2I7 Ho.0772 -O.193 -0,0502 -0,166 -0. 233 28.5% Net Final Momentum = Net Initial Momentum = Percent difference = 4. In a totally inelastic collision the objects stick together after the collision and move off as one. Kinetic energy is not conserved in this type of collision. What happens to the kinetic energy that is present before the collision? Compute the kinetic energy of the system before and after the collision for one of the inelastic collisions. Form a ratio of the KE over the KE;. KE = mv? (11.30)

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Table 11.5: Totally Inelastic Collision Between Two Moving Carts of Unequal Mass (Velcro) Object Net Mass (kg) Color of Cart (m/s) (kg -m/s) (m/s) (kg-m/s) 0.76K9F0,40l0.310-o.153 -0.116 0.2b kg -0. 233 28.5% GREEN Gray 0.297 to.0772 -0,193 -0.0502 -0.166 Net Final Momentum = Net Initial Momentum = Percent difference = 4. In a totally inelastic collision the objects stick together after the collision and move off as one. Kinetic energy is not conserved in this type of collision. What happens to the kinetic energy that is present before the collision? Compute the kinetic energy of the system before and after the collision for one of the inelastic collisions. Form a ratio of the KEf over the KE;. 1 KE = (11.30)