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Chapter 9 Linear Momentum and Collisions EXAMPLES. Example 9.1 The Archer. The archer of mass 60kg is standing on a frictionless surface (ice). He fires a 0.50kg arrow horizontally at 50 m/s . With what velocity does the archer move across the ice after firing the arrow? Can we use:
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Example 9.1 The Archer • The archer of mass 60kg is standing on a frictionless surface (ice). He fires a 0.50kg arrow horizontally at 50 m/s. With what velocity does the archer move across the ice after firing the arrow? • Can we use: • Newton’s Second Law ? NO No information about F or a • Energy? NO No information about work or energy • Momentum? YES • The System will be: the archer with bow (particle 1) and the arrow (particle 2)
Example 9.1 The Archer, final • ΣFx = 0, so it is isolated in terms of momentum in the x-direction • Total momentum before releasing the arrow is 0: p1i + p2i = 0 • The total momentum after releasing the arrow is p1f + p2f = 0 m1v1f + m2v2f = 0 v1f = – (m2/m1 )v2f v1f = – (0.50kg/60kg)(50.0î)m/s v1f = –0.42 î m/s • The archer will move in the opposite direction of the arrow after the release • Agrees with Newton’s Third Law • Because the archer is much more massive than the arrow, his acceleration and velocity will be much smaller than those of the arrow
Example 9.2 Railroad Cars Collide(Perfectly Inelastic Collision) • Initial Momentum = Final Momentum (One-Dimension) If: m1v1+m2v2 = (m1 + m2)v’ Given: v2 = 0, v’1= v’2 = v’ = ? v’ =m1v1/(m1 + m2) = 240,000/20,000m/s v’ =12 m/s m1 = 10,000kg m2 = 10,000kg m1 + m2 = 20,000 kg
Example 9.3 How Good Are the Bumpers? • Mass of the car is 1500 kg. The collision lasts 0.105s. • Find: p =I and the average force (Favg) exerted on the car.
Example 9.4 Tennis Ball Hits the Wall • p =I ? Given to the ball. If m = 0.060 kg and v = 8.00 m/s p =I : change in momentum wall. • Momentum ∕∕ to wall doesn’t change. • Impulsewill be wall. • Take + direction toward wall, p =I = mv = m (vf – vi) p =I = m(–vsin45–vsin45) p =I = –2mvsin45 = –2.1 N.s • Impulse on wall is in opposite direction: 2.1 N.s vf = –vsin45 vi = vsin45
Example 9.5 Explosion as a Collision • Initial Momentum = Final Momentum (One-Dimension) m1v1+m2v2 = m1v’1+ m2v’2 • Initially: v = 0 Explodes! • Finally: mv = 0 = m2v’2 + m1v’1 Given: m1 , m2, v’2, you may compute v’1 v’1= – (m2/m1)v’2 m v = 0
Example 9.6 Rifle Recoil • Momentum Before = Momentum After m1v1+m2v2 = m1v’1+ m2v’2 • Given:mB= 0.02 kg, mR= 5.00 kg, v’B = 620 m/s 0 = mBv’B + mRv’R v’R=–mBv’B/mR =– (0.02)(620)/5.00 m/s = – 2.48 m/s (to the left, of course!)
Example 9.7 Ballistic Pendulum • Perfectly inelastic collision – the bullet is embedded in the block of wood • Momentum equation will have two unknowns • Use conservation of energy from the pendulum to find the velocity just after the collision • Then you can find the speed of the bullet
Example 9.7 Ballistic Pendulum, final • Before: • Momentum Conservation: • After: • Conservation of energy: Solving for vB: Replacing vB into 1st equation and solving for v1A:
Example 9.8 Collision at an Intersection • Mass of the car mc= 1500kg Mass of the van mv = 2500kg • Find vf if this is a perfectly inelastic collision (they stick together). • Before collision: • The car’smomentum is: Σpxi= mcvc Σpxi= (1500)(25) = 3.75x104 kg·m/s • The van’smomentum is: Σpyi= mvvv Σpyi= (2500)(20) = 5.00x104 kg·m/s • After collision: both have the same x- and y-components: Σpxf = (mc + mv )vf cos Σpyf = (mc + mv )vf sin
Example 9.8 Collision at an Intersection, final • Because the total momentum is both directions is conserved: Σpxf = Σpxi 3.75x104 kg·m/s = (mc + mv )vf cos = 4000vf cos (1) Σpyf = Σpyi 5.00x104 kg·m/s = (mc + mv )vf sin = 4000vf sin (2) • Dividing Eqn (2) by (1) 5.00/3.75 =1.33 = tan = 53.1° • Substituting in Eqn (2) or (1) 5.00x104 kg·m/s = 4000vf sin53.1° vf =5.00x104/(4000sin53.1° ) vf =15.6m/s
Example 9.9 Center of Mass (Simple Case) • Both masses are on the x-axis • The center of mass (CM) is on the x-axis • One dimension xCM = (m1x1 + m2x2)/M M = m1+m2 xCM≡(m1x1 + m2x2)/(m1+m2) • The center of mass is closer to the particle with the larger mass • If: x1 = 0, x2 = d & m2 = 2m1 xCM≡(0 + 2m1d)/(m1+2m1) xCM≡2m1d/3m1 xCM = 2d/3
Example 9.10 Three Guys on a Raft A group of extended bodies, each with a known CM and equivalent mass m. Find the CM of the group. xCM = (Σmixi)/Σmi xCM = (mx1+ mx2+ mx3)/(m+m+m) xCM = m(x1+ x2+ x3)/3m = (x1+ x2+ x3)/3 xCM = (1.00m + 5.00m + 6.00m)/3 = 4.00m
Example 9.11 Center of Mass of a Rod • Find the CM position of a rod of mass M and length L. The location is on the x-axis (A). Assuming the road has a uniform mass per unit length λ = M/L (Linear mass density) • From Eqn 9.32 • But:λ = M/L
Example 9.11 Center of Mass of a Rod, final. (B). Assuming now that the linear mass density of the road is no uniform: λ = x • The CM will be: • But mass of the rod and are related by: The CM will be:
Material for the Final Exam • Examples to Read!!! • Example 9.2 (page 239) • Example 9.5 (page 247) • Example 9.10 (page 256) • Material from the book to Study!!! • Objective Questions: 7-8-13 • Conceptual Questions: 3-5-6 • Problems: 1-9-11-15-25-26-27-37-40-65