A car moving with an initial speed v collides with a second stationary car that is one-half as massive After the collision the first car moves in the same direction as before with a speed v/3. a) Draw diagram b) Find the final speed of the second car. c) Compare initial and final kinetic energies of the system. d) Is collision elastic or inelastic?

Part A and B on paper

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### Collision and Conservation of Momentum #### Problem Statement: A car moving with an initial speed \( v \) collides with a second stationary car that is one-half as massive. After the collision, the first car moves in the same direction as before with a speed \( \frac{v}{3} \). ### Tasks: a) Draw a diagram b) Find the final speed of the second car. c) Compare the initial and final kinetic energies of the system. d) Determine if the collision is elastic or inelastic. #### Solution: **a) Draw a diagram:** **Before Collision:** - Car 1 (mass = m, speed = v) ➔ - Car 2 (mass = 0.5m, speed = 0) (stationary) \[ \rightarrow \ \text{Collision} \ \rightarrow \] **After Collision:** - Car 1 (mass = m, speed = \(\frac{v}{3}\)) ➔ - Car 2 (mass = 0.5m, speed = \(v_2\)) ➔ **b) Find the final speed of the second car:** Using conservation of momentum: - **Initial Momentum:** \[ p_{initial} = m \cdot v + 0.5m \cdot 0 = mv \] - **Final Momentum:** \[ p_{final} = m \cdot \frac{v}{3} + 0.5m \cdot v_2 \] \[ mv = m \cdot \frac{v}{3} + 0.5m \cdot v_2 \] Dividing the equation by \( m \): \[ v = \frac{v}{3} + 0.5v_2 \] Solving for \( v_2 \): \[ v - \frac{v}{3} = 0.5v_2 \] \[ \frac{2v}{3} = 0.5v_2 \] \[ v_2 = \frac{4v}{3} \] Therefore, the final speed of the second car, \( v_2 \), is \( \frac{4v}{3} \). **c) Compare initial and final kinetic energies of the system:** - **Initial K