Collisions and Conservation of Momentum

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Collisions and Conservation of Momentum

A Collision of Two Masses When two masses m1 and m2 collide, we will use the symbol u to describe velocities before collision. m1 u1 m2 u2 Before The symbol v will describe velocities after collision. After m1 v1 m2 v2

A Collision of Two Blocks m1 u1 m2 u2 Before Collision m1 B m2 “u”= Before “v” = After m2 v2 m1 v1 After

Conservation of Energy m1 m2 u1 u2 The kinetic energy before colliding is equal to the kinetic energy after colliding plus the energy lost in the collision.

Example 1. A 2-kg mass moving at 4 m/s collides with a 1-kg mass initially at rest. After the collision, the 2-kg mass moves at 1 m/s and the 1-kg mass moves at 2 m/s. What energy was lost in the collision? It’s important to draw and label a sketch with appropriate symbols and given information. m2 u2 = 0 m1 u1 = 4 m/s m1 = 2 kg m1 = 1 kg BEFORE m2 v2 = 2 m/s m1 v1 = 1 m/s m1 = 2 kg m1 = 1 kg AFTER

Energy Conservation: K(Before) = K(After) + Loss Example 1 (Continued). What energy was lost in the collision? Energy is conserved. m2 u2 = 0 m1 u1 = 4 m/s m1 = 2 kg m2 = 1 kg v2 = 2 m/s v1 = 1 m/s BEFORE: AFTER Energy Conservation: K(Before) = K(After) + Loss Loss = 16 J – 3 J Energy Loss = 13 J

mBvB - mBuB = -(mAvA - mAuA) Impulse and Momentum A B uA uB vA vB Impulse = Dp -FA Dt FB Dt FDt = mvf– mvo Opposite but Equal F Dt FBDt = -FADt mBvB - mBuB = -(mAvA - mAuA) Simplifying: mAvA + mBvB = mAuA + mBuB

Conservation of Momentum The total momentum AFTER a collision is equal to the total momentum BEFORE. mAvA + mBvB = mAuA + mBuB A B uA uB vA vB -FADt FB Dt Recall that the total energy is also conserved: Kinetic Energy: K = ½mv2 KA0 + KB0 = KAf + KBf + Loss

mAvA + mBvB = mAuA + mBuB mBvB mA mAvA = - mBvB vA = - Example 2: A 2-kg block A and a 1-kg block B are pushed together against a spring and tied with a cord. When the cord breaks, the 1-kg block moves to the right at 8 m/s. What is the velocity of the 2 kg block? A B The initial velocities are zero, so that the total momentum before release is zero. mAvA + mBvB = mAuA + mBuB vA = - mBvB mA mAvA = - mBvB

Example 2 (Continued) vA2 mAvA+ mBvB = mAuA + mBuB mBvB mA mAvA = - mBvB vA = - mBvB mA A B 2 kg 1 kg 8 m/s vA2 vA = - (1 kg)(8 m/s) (2 kg) vA = - 4 m/s

Elastic or Inelastic? An elastic collision loses no energy. The deform-ation on collision is fully restored. In an inelastic collision, energy is lost and the deformation may be permanent. (Click it.)

Perfectly Inelastic Collisions Collisions where two objects stick together and have a common velocity after impact. Before After

P. Inelastic collision: Example 3: A 60-kg football player stands on a frictionless lake of ice. He catches a 2-kg football and then moves at 40 cm/s. What was the initial velocity of the football? A Given: uB= 0; mA= 2 kg; mB= 60 kg; vA= vB= vC vC = 0.4 m/s B Momentum: mAvA + mBvB = mAuA + mBuB P. Inelastic collision: (mA + mB)vC = mAuA (2 kg + 60 kg)(0.4 m/s) = (2 kg)uA uA= 12.4 m/s

Example 3 (Cont.): How much energy was lost in catching the football? ½(2 kg)(12.4 m/s)2 = ½(62 kg)(0.4 m/s)2 + Loss 154 J = 4.96 J + Loss Loss = 149 J 97% of the energy is lost in the collision!!

General: Perfectly Inelastic Collisions where two objects stick together and have a common velocity vC after impact. Conservation of Momentum: Conservation of Energy:

Common speed after colliding: 2.4 m/s. Example 4. An 87-kg skater B collides with a 22-kg skater A initially at rest on ice. They move together after the collision at 2.4 m/s. Find the velocity of the skater B before the collision. A B uB = ? uA = 0 Common speed after colliding: 2.4 m/s. 22 kg 87 kg vB= vA = vC = 2.4 m/s (87 kg)uB = (87 kg + 22 kg)(2.4 m/s) (87 kg)uB =262 kg m/s uB = 3.01 m/s

(0.150 kg)vA+ (2 kg)(40 m/s) = (0.150 kg)(715 m/s) Example 6. Nonperfect inelastic: A 0.150 kg bullet is fired at 715 m/s into a 2-kg wooden block at rest. The velocity of block afterward is 40 m/s. The bullet passes through the block and emerges with what velocity? B A uB = 0 (0.150 kg)vA+ (2 kg)(40 m/s) = (0.150 kg)(715 m/s) 0.150vA+ (80 m/s) = (107 m/s) 0.150vA = 27.2 m/s) vA = 181 m/s

Completely Elastic Collisions Collisions where two objects collide in such a way that zero energy is lost in the process. APPROXIMATIONS!

Velocity in Elastic Collisions uB uA 1. Zero energy lost. A B 2. Masses do not change. vA vB A B 3. Momentum conserved. Equal but opposite impulses (F Dt) means that: (Relative Dv After) = - (Relative Dv Before) vA - vB = - (uA - uB) For elastic collisions:

From conservation of energy (relative v): Example 6: A 2-kg ball moving to the right at 1 m/s strikes a 4-kg ball moving left at 3 m/s. What are the velocities after impact, assuming complete elasticity? A B 3 m/s 1 m/s vA vB 1 kg 2 kg vA - vB = - (uA - uB) vA - vB = uB - uA vA - vB = (-3 m/s) - (1 m/s) From conservation of energy (relative v): vA - vB = - 4 m/s

Example 6 (Continued) mAvA + mBvB = mAuA + mBuB vA + 2vB = -5 m/s 1 kg 2 kg Energy: vA - vB = - 4 m/s Momentum also conserved: mAvA + mBvB = mAuA + mBuB (1 kg)vA+(2 kg)vB=(1 kg)(1 m/s)+(2 kg)(-3 m/s) vA + 2vB = -5 m/s Two independent equations to solve: vA - vB = - 4 m/s

Example 6 (Continued) vA + 2vB = -5 m/s vA - vB = - 4 m/s vA 1 kg 2 kg vA + 2vB = -5 m/s vA - vB = - 4 m/s Subtract: 0 + 3vB2 = - 1 m/s vB = - 0.333 m/s vA2 - (-0.333 m/s) = - 4 m/s Substitution: vA= -3.67 m/s vA - vB = - 4 m/s

(0.150 kg)vA+ (2 kg)(40 m/s) = (0.150 kg)(715 m/s) Example 7. A 0.150 kg bullet is fired at 715 m/s into a 2-kg wooden block at rest. The velocity of block afterward is 40 m/s. The bullet passes through the block and emerges with what velocity? B A uB = 0 (0.150 kg)vA+ (2 kg)(40 m/s) = (0.150 kg)(715 m/s) 0.150vA+ (80 m/s) = (107 m/s) 0.150vA = 27.2 m/s) vA = 181 m/s

Example 8a: P. inelastic collision: Find vC. B 5 kg 7.5 kg uB=0 2 m/s After hit: vB= vA= vC (5 kg)(2 m/s) = (5 kg + 7.5 kg)vC A B Common vC after vC 12.5 vC =10 m/s vC = 0.800 m/s In an completely inelastic collision, the two balls stick together and move as one after colliding.

Example 8. (b) Elastic collision: Find vA2 and vB2 5 kg 7.5 kg vB1=0 2 m/s Conservation of Momentum: (5 kg)(2 m/s) = (5 kg)vA2 + (7.5 kg) vB A B vA vB 5 vA + 7.5 vB = 10 m/s For Elastic Collisions: Continued . . .

Example 8b (Cont). Elastic collision: Find vA & vB Solve simultaneously: A B 5 kg 7.5 kg vB =0 2 m/s vA vB x (-5) 5 vA + 7.5 v B = 10 m/s 5 vA + 7.5 vB = 10 m/s -5 vA + 5 vB = +10 m/s vA - 1.60 m/s = -2 m/s vA = -0.400 m/s 12.5 vB = 20 m/s vB = 1.60 m/s

General: Completely Elastic Collisions where zero energy is lost during a collision (an ideal case). Conservation of Momentum: Conservation of Energy:

Conservation of Momentum: Summary of Formulas: Conservation of Momentum: Conservation of Energy: For elastic only:

The End