lecture ch 07

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Chapter 7 Linear Momentum

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Page 1: Lecture Ch 07

Chapter 7

Linear Momentum

Page 2: Lecture Ch 07

Units of Chapter 7

•Momentum and Its Relation to Force

•Conservation of Momentum

•Collisions and Impulse

•Conservation of Energy and Momentum in Collisions

•Elastic Collisions in One Dimension

•Inelastic Collisions

•Center of Mass (CM)

Page 3: Lecture Ch 07

Momentum is a vector symbolized by the symbol p, and is defined as

p = mv (a vector || v)

SI Units: kg m/s = N s

Question: How is the momentum of a body change?

Chapter 7

Linear Momentum

Answer: By the application of a force F

(7-1)

Page 4: Lecture Ch 07

Momentum: p = mv

The rate of change of momentum is equal to the net force: ∑F = p/t

Also considered as the most general statement of Newton’s 2nd Law

Is more general than ∑F = ma because it allows for the mass m to change with time also!

Example, rocket motion! Later!

7-1 Momentum and Its Relation to Force

in time change

momentumin change body aon acting force Total

(7-2)

Page 5: Lecture Ch 07

7-1 Momentum and Its Relation to Force

Newton’s 2nd Law (General Form!) ∑F = p/t

Note: if m is constant, becomes: ∑F = p/t = (mv)/t = m(v/t) = ma

m = constant. Initial momentum p0 = mv0, Final momentum p = mv. becomes:

∑F = p/t = m(v-v0)/t = m(v/t) = ma

(as before)

Page 6: Lecture Ch 07

∑F = p/t Initial p = mv

Final p = 0Water rate = 1.5 kg/s

p = 0 – mv F = (p/t) = [(0-mv)/t] = - mv/ t

m = 1.5 kg every second On the water F = -30 NOn the car F = 30 N

Example 7-2

Page 7: Lecture Ch 07

Experimental fact (provable from Newton’s Laws):

For two colliding objects, (zero external force) the total momentum is conserved (constant) throughout the collision

The total (vector) momentum before the collision = the total (vector) momentum after the collision.

Law of Conservation of Momentum

7-2 Conservation of Momentum

Page 8: Lecture Ch 07

7-2 Conservation of MomentumDuring a collision, measurements show that the total momentum does not change:

Ptotal= pA + pB =(pA)+ (pB) = constantOr:ptotal = pA + pB = 0

pA = mA vA , pB = mBvB Initial momenta

(pA) = mA(vA) (pB) = mB(vB) Final momenta

the vector sum is constant!

Page 9: Lecture Ch 07

• Collision: m1v1+m2v2 = m1 (v1) + m2 (v2) • Proof, using Newton’s Laws:

Force on 1, due to 2,

F12 = p1/t

= m1[(v1) - v1]/t

Force on 2, due to 1,

F21 = p2/t

= m2[(v2) - v2]/ t

Newton’s 3rd Law: F21 = - F12

-m1[(v1) - v1]/t = m2[(v2) - v2]/t

OR: m1v1+m2v2 = m1 (v1) + m2 (v2) Proven!

A→1B→2

Page 10: Lecture Ch 07

7-2 Conservation of Momentum

More formally, the law of conservation of momentum states:

The total momentum of an isolated system of objects remains constant.

Page 11: Lecture Ch 07

m1v1+m2v2 = (m1 + m2)V v2 = 0, (v1) = (v2) = V V = [(m1v1)/(m1 + m2)] = 12 m/s

Example 7-3

Initial Momentum = Final Momentum (1D)

Page 12: Lecture Ch 07

7-2 Conservation of Momentum

Momentum conservation works for a rocket as long as we consider the rocket and its fuel to be one system, and account for the mass loss of the rocket.

0 = Procket - Pgas

Page 13: Lecture Ch 07

Momentum Before = Momentum After

m1v1+m2v2 = m1(v1) + m2(v2) mB = 0.02 kg mR = 5.0 kg (vB) = 620 m/s

0 = mB (vB) + mR(vR) (vR) = - 2.5 m/s (to left, of course!)

Example 7-4

Page 14: Lecture Ch 07

7-3 Collisions and Impulse

During a collision, objects are deformed due to the large forces involved.

Since , we can

write

The definition of impulse:

(7-5)

Page 15: Lecture Ch 07

7-3 Collisions and Impulse

Since the time of the collision is very short, we need not worry about the exact time dependence of the force, and can use the average force.

Impulse here is the area under the Fc vs. t curve.

Page 16: Lecture Ch 07

7-3 Collisions and ImpulseThe impulse tells us that we can get the same change in momentum with a large force acting for a short time, or a small force acting for a longer time.

This is why you should bend your knees when you land; why airbags work; and why landing on a pillow hurts less than landing on concrete.

Page 17: Lecture Ch 07

• Advantage of bending knees when landing!

a) m =70 kg, h =3.0 m

Impulse: p = ?

Ft= p = m(0-v)

First, find v (just before

hitting): KE + PE = 0

(½)m(v2 -0) + mg(0 - h) = 0

v = 7.7 m/s

Or using:

Impulse: p = -540 N s

Example 7-6

)(2 020

2 yyavv

Page 18: Lecture Ch 07

• Advantage of bending knees when landing!

Impulse: p = -540 N s

m =70 kg, h =3.0 m, F = ?

b) Stiff legged: v = 7.7 m/s to

v = 0 in d = 1 cm (0.01m)!

average v = (½ )(7.7 +0) = 3.8 m/s

Time t = d/v = 2.6 10-3 s

F = |p/t| = 2.1 105 N

(Net force upward on person)

From free body diagram,

F = Fgrd - mg 2.1 105 N

Enough to fracture leg bone!!!

Example 7-6

Page 19: Lecture Ch 07

Example 7-6• Advantage of bending knees when landing!

Impulse: p = -540 N s

m =70 kg, h =3.0 m, F = ?

c) Knees bent: v = 7.7 m/s to

v = 0 in d = 50 cm (0.5m)

v = (½ )(7.7 +0) = 3.8 m/s

Time t = d/v = 0.13 s

F = |p/t| = 4.2 103 N

(Net force upward on person)

From free body diagram,

F = Fgrd - mg 4.9 103 N

Leg bone does not break!!!

Page 20: Lecture Ch 07

• Impulse:

m = 0.060 kg v = 25 m/s

p = change in momentum wall.• Momentum || to wall does not

change. Impulse will be wall.

Take + direction toward wall,

Impulse = p = mv

= m[(- v sinθ) - (v sinθ)]

= -2mv sinθ = - 2.1 N s.

Impulse on wall is in

opposite direction:

2.1 N s.

Problem 17

vi = v sinθ vf = - v sinθ

Page 21: Lecture Ch 07

Momentum is ALWAYS (!!!) conserved in a collision!

m1v1 + m2v2 = m1(v1) + m2(v2)HOLDS for ALL collisions!

For Elastic Collisions ONLY (!!)

Total Kinetic energy (KE) is conserved!!

(KE)before = (KE)after

(½)m1(v1)2 + (½) m2(v2)2

= (½)m1(v1)2 + (½)m2 (v2)2

7-4 Conservation of Energy and Momentum in Collisions

Page 22: Lecture Ch 07

7-4 Conservation of Energy and Momentum in Collisions

Momentum is conserved in all collisions.

Collisions in which kinetic energy is conserved as well are called elastic collisions, and those in which it is not are called inelastic.

Page 23: Lecture Ch 07

7-5 Elastic Collisions in One Dimension

Here we have two objects colliding elastically. We know the masses and the initial speeds.

Since both momentum and kinetic energy are conserved, we can write two equations. This allows us to solve for the two unknown final speeds.

Page 24: Lecture Ch 07

• Special case: Head-on Elastic Collisions.– Momentum is conserved (ALWAYS!)

Pbefore = Pafter

m1v1 + m2v2 = m1v1 + m2v2 v1, v2, v1, v2 are one dimensional vectors!

– Kinetic Energy is conserved (ELASTIC!)

(KE)before = (KE)after

(½)m1(v1)2 + (½)m2(v2)2 = (½)m1(v1)2 + (½) m2 (v2)2

– 2 equations, 6 quantities: v1,v2,v1, v2, m1,m2

Clearly, must be given 4 out of 6 to solve problems! Solve with CAREFUL algebra!!

Page 25: Lecture Ch 07

m1v1 + m2v2 = m1v1 + m2v2 (1)

(½)m1(v1)2 + (½)m2(v2)2 = (½)m1(v1)2 + (½) m2 (v2)2 (2)

• Now, some algebra with (1) & (2), the results of

which will help to simplify problem solving:

– Rewrite (1) as: m1(v1 - v1) = m2(v2 - v2) (a)

– Rewrite (2) as:

m1[(v1)2 - (v1)2] = m2[(v2)2 - (v2)2] (b)

– Divide (b) by (a):

v1 + v1 = v2 + v2 or

v1 - v2 = v2 - v1 = -(v1 - v2) (3) Relative velocity before= - Relative velocity after

Elastic head-on (1d) collisions only!!

Page 26: Lecture Ch 07

• Summary: 1d Elastic collisions: Rather than directly use momentum conservation + KE conservation, often convenient to use:

Momentum conservation:

m1v1 + m2v2 = m1v1 + m2v2 (1)

along with:

v1 - v2 = v2 - v1 = -(v1 - v2) (3)

• (1) & (3) are equivalent to momentum conservation + KE conservation, since (3) was derived from these conservation laws!

Page 27: Lecture Ch 07

m1 = m2 = m, v1 = v, v2 = 0, v1 = ?, v2 = ?

• Momentum Conservation: mv +m(0)=mv1 +mv2

Masses cancel v +0 = v1 + v2 (I)• Relative velocity results for elastic head on collision:

v1 - v2 = v2 - v1 v - 0 = v2 - v1 (II)

Solve (I) & (II) simultaneously for v1 & v2 :

v1 = 0, v2 = v

Ball 1: to rest. Ball 2 moves with original velocity of ball 1

Example 7-7: Pool (Billiards)

Page 28: Lecture Ch 07

7-6 Inelastic Collisions

With inelastic collisions, some of the initial kinetic energy is lost to thermal or potential energy. It may also be gained during explosions, as there is the addition of chemical or nuclear energy.

A completely inelastic collision is one where the objects stick together afterwards, so there is only one final velocity.

Page 29: Lecture Ch 07

Momentum Conservation mv = (m + M)v´

Energy Conservation (½)(m +M)(v´)2 = (m + M)gh v´= (2gh)½

v = [1 +(M/m)](2gh)½

Ex. 7-10 & Prob. 32 (Inelastic Collisions)

Page 30: Lecture Ch 07

• Up to now, we’ve been mainly concerned with the motion of single (point) particles.

• To treat extended bodies, we’ve approximated the body as a point particle & treated it as if it had all of its mass at a point!

• How is this possible?• Real, extended bodies have complex motion,

including (possibly): translation, rotation, & vibration!

7-8 Center of Mass

Page 31: Lecture Ch 07

7-8 Center of MassIn (a), the diver’s motion is pure translation; in (b) it is translation plus rotation.

There is one point that moves in the same path a particle would take if subjected to the same force as the diver. This point is called the center of mass (CM).

Page 32: Lecture Ch 07

7-8 Center of Mass

The general motion of an object can be considered as the sum of the translational motion of the CM, plus rotational, vibrational, or other forms of motion about the CM.

Page 33: Lecture Ch 07

7-8 Center of Mass

For two particles, the center of mass lies closer to the one with the most mass:

where M is the total mass.

Page 34: Lecture Ch 07

7-8 Center of Mass

The center of gravity is the point where the gravitational force can be considered to act. It is the same as the center of mass as long as the gravitational force does not vary among different parts of the object.

Page 35: Lecture Ch 07

7-8 Center of Mass

The center of gravity can be found experimentally by suspending an object from different points. The CM need not be within the actual object – a doughnut’s CM is in the center of the hole.

Page 36: Lecture Ch 07

Summary of Chapter 7

• Momentum of an object:

• Newton’s second law:

•Total momentum of an isolated system of objects is conserved.

• During a collision, the colliding objects can be considered to be an isolated system even if external forces exist, as long as they are not too large.

• Momentum will therefore be conserved during collisions.

Page 37: Lecture Ch 07

• In an elastic collision, total kinetic energy is also conserved.

• In an inelastic collision, some kinetic energy is lost.

• In a completely inelastic collision, the two objects stick together after the collision.

• The center of mass of a system is the point at which external forces can be considered to act.

Summary of Chapter 7, cont.