class starter (10 minutes write questions) 1.if a car travels west 75 kilometers takes a u- turn and...
TRANSCRIPT
Class StarterClass Starter(10 minutes write questions)(10 minutes write questions)
1.1. If a car travels west 75 kilometers takes a u-If a car travels west 75 kilometers takes a u-turn and travels back east 25 kilometers turn and travels back east 25 kilometers what is the car’s final displacement?what is the car’s final displacement?
2.2. If a car at rest, traveled north 5.5 s and If a car at rest, traveled north 5.5 s and reached a final velocity of 22.0 m/s, what reached a final velocity of 22.0 m/s, what was the car’s acceleration?was the car’s acceleration?
3.3. If a force propels a car to move 300km in If a force propels a car to move 300km in 4hrs what is the average speed (do not need 4hrs what is the average speed (do not need to convert)?to convert)?
50 km west
4.0 m/s2
75 km/h
Starter (15 minutes)Starter (15 minutes)
Get a coach workbook from the second Get a coach workbook from the second shelf of the book shelf and read pages shelf of the book shelf and read pages 92-94 (Read carefully their MAY be a pop 92-94 (Read carefully their MAY be a pop quiz on the reading)quiz on the reading)
Write questions 1-5 on page 95 and Write questions 1-5 on page 95 and answer each question correctly.answer each question correctly.
StarterStarter
Read pages 96-99 in the coach Read pages 96-99 in the coach workbook.workbook.
Write the questions and answers for Write the questions and answers for problems 1-3 on page 99.problems 1-3 on page 99.
Let me know if you did not finish the Let me know if you did not finish the survey from Friday so you can complete survey from Friday so you can complete it.it.
Forces & Forces & MotionMotionChapter 12Chapter 12
WHAT IS A FORCE?WHAT IS A FORCE? a push or a pulla push or a pull one body exerts a force one body exerts a force
on anotheron another SI units are Newton SI units are Newton
(N), 1N=1kgm/s(N), 1N=1kgm/s22
= ( m )( a )= ( m )( a )
F
m a
ForceForce
ForceForce What forces are being What forces are being
exerted on the football?exerted on the football?
Fkick
Fgrav
ForceForce Balanced ForcesBalanced Forces
forces acting on forces acting on an object that are an object that are opposite in opposite in direction and direction and equal in sizeequal in size
no change in no change in velocityvelocity
Effects of forces on objectsEffects of forces on objects
Balanced forces Balanced forces
ForceForce Net ForceNet Force
unbalanced forces that are not opposite unbalanced forces that are not opposite and equaland equal
velocity changes (object accelerates)velocity changes (object accelerates)
Ffriction
W
Fpull
Fnet
NN
A group of animals are playing tug-of-war. A group of animals are playing tug-of-war. The elephants pull the rope with a force of The elephants pull the rope with a force of 100N to the left. The donkeys pull the rope 100N to the left. The donkeys pull the rope with a force of 105N to the right. Which with a force of 105N to the right. Which way will the rope accelerate?way will the rope accelerate?
To the RIGHTTo the RIGHT
FrictionFriction
FrictionFriction force that opposes motion between 2 force that opposes motion between 2
surfacessurfaces depends on the:depends on the:
types of surfacestypes of surfaces force between the surfacesforce between the surfaces
FrictionFriction
Four Types of FrictionFour Types of FrictionStatic FrictionStatic Friction – force that acts on objects that – force that acts on objects that
are not moving. (Couch Potato)are not moving. (Couch Potato)Sliding FrictionSliding Friction - force that opposes the - force that opposes the
direction of motion of an object as it slides direction of motion of an object as it slides over a surface. (Ice skating or bobsledding)over a surface. (Ice skating or bobsledding)
Rolling FrictionRolling Friction – friction force that acts on – friction force that acts on rolling objects. (Rollerblading)rolling objects. (Rollerblading)
Fluid FrictionFluid Friction – force that opposes the motion – force that opposes the motion of an object through a fluid. (Planes flying or of an object through a fluid. (Planes flying or submarines traveling)submarines traveling)
FrictionFriction
Friction is greater...Friction is greater... between rough surfacesbetween rough surfaces when there’s a greater force when there’s a greater force
between the surfaces between the surfaces (e.g. more weight)(e.g. more weight)
GravityGravity
GravityGravity
force of attraction between any two force of attraction between any two objects in the universeobjects in the universe
increases as...increases as... mass increasesmass increases distance decreasesdistance decreases
GravityGravity
Who experiences more gravity - the astronaut Who experiences more gravity - the astronaut or the politician?or the politician?
less distance
more mass
Which exerts more gravity - Which exerts more gravity -
the Earth or the moon?the Earth or the moon?
GravityGravity WeightWeight
the force of gravity on an objectthe force of gravity on an object
MASSalways the same
(kg)
WEIGHTdepends on gravity
(N)
W = mgW: weight (N)m: mass (kg)g: acceleration due
to gravity (m/s2)
GravityGravity Would you weigh more on Earth or Would you weigh more on Earth or
Jupiter?Jupiter?
greater gravitygreater gravity
greater weightgreater weight
greater massgreater mass
Jupiter because...Jupiter because...
GravityGravity Accel. due to gravity Accel. due to gravity (g)(g)
In the absence of air resistance, In the absence of air resistance, allall falling falling objects have the same acceleration!objects have the same acceleration!
On Earth:On Earth: g g = 9.8 m/s = 9.8 m/s22
mW
g
elephant
m
Wg
featherAnimation from “Multimedia Physics Studios.”
Newton’s First LawNewton’s First Law
Newton’s First Law of MotionNewton’s First Law of Motion An object at rest will remain at rest and An object at rest will remain at rest and
an object in an object in motionmotion will continue moving will continue moving at a at a constant velocityconstant velocity unless acted upon unless acted upon by a by a net forcenet force..
Newton’s First LawNewton’s First Law Newton’s First Law of MotionNewton’s First Law of Motion
““Law of Inertia”Law of Inertia”
InertiaInertia tendency of an object to resist any change in its tendency of an object to resist any change in its
motionmotion increases as mass increasesincreases as mass increases
Newton’s Second LawNewton’s Second Law
Newton’s Second Law of MotionNewton’s Second Law of Motion The acceleration of an object is The acceleration of an object is directly proportionaldirectly proportional
to the net force acting on it and to the net force acting on it and inversely inversely proportionalproportional to its mass. to its mass.
F = ma
Newton’s Second LawNewton’s Second Law
F = maF: force (N)m: mass (kg)a: accel (m/s2)
1 N = 1 kg ·m/s2
am
F
a
Fm
CalculationsCalculations What force would be required to accelerate a 40 What force would be required to accelerate a 40
kg mass by 4 m/skg mass by 4 m/s22??
GIVEN:
F = ?
m = 40 kg
a = 4 m/s2
WORK:
F = ma
F = (40 kg)(4 m/s2)
F = 160 N
m
F
a
CalculationsCalculations A 4.0 kg shotput is thrown with 30 N of force. A 4.0 kg shotput is thrown with 30 N of force.
What is its acceleration?What is its acceleration?
GIVEN:
m = 4.0 kg
F = 30 N
a = ?
WORK:
a = F ÷ m
a = (30 N) ÷ (4.0 kg)
a = 7.5 m/s2
m
F
a
CalculationsCalculations Mr. Keller weighs 745 N. What is his mass? Mr. Keller weighs 745 N. What is his mass?
GIVEN:
F(W) = 745 N
m = ?
a(g) = 9.8 m/s2
WORK:
m = F ÷ a
m = (745 N) ÷ (9.8 m/s2)
m = 76.0 kg
m
F
a
ConcepTestConcepTest
Is the following statement true or false?Is the following statement true or false? An astronaut has less mass on the moon An astronaut has less mass on the moon
since the moon exerts a weaker since the moon exerts a weaker gravitational force.gravitational force. False! Mass does not depend on gravity, weight False! Mass does not depend on gravity, weight
does. The astronaut has less does. The astronaut has less weightweight on the on the moon.moon.
Newton’s Third LawNewton’s Third Law Newton’s Third Law of MotionNewton’s Third Law of Motion
When one object exerts a force on a When one object exerts a force on a second object, the second object exerts second object, the second object exerts an equal but opposite force on the first.an equal but opposite force on the first.
Newton’s Third LawNewton’s Third Law Problem:Problem:
How can a horse How can a horse pull a cart if the cart pull a cart if the cart is pulling back on is pulling back on the horse with an equal but opposite force? the horse with an equal but opposite force?
NO!!!
Aren’t these “balanced forces” resulting in no Aren’t these “balanced forces” resulting in no acceleration?acceleration?
Newton’s Third LawNewton’s Third Law
forces are equal and opposite but act on forces are equal and opposite but act on differentdifferent objects objects
they are not “balanced forces”they are not “balanced forces” the movement of the horse depends on the the movement of the horse depends on the
forces acting forces acting on the horseon the horse
Explanation:Explanation:
Newton’s Third LawNewton’s Third Law
Action-Reaction PairsAction-Reaction Pairs
The hammer exerts a The hammer exerts a force on the nail to the force on the nail to the right.right.
The nail exerts an equal The nail exerts an equal but opposite force on but opposite force on the hammer to the left.the hammer to the left.
Newton’s Third LawNewton’s Third Law
Action-Reaction PairsAction-Reaction Pairs The rocket exerts a The rocket exerts a
downward force on the downward force on the exhaust gases.exhaust gases.
The gases exert an equal The gases exert an equal but opposite upward force but opposite upward force on the rocket.on the rocket.
FG
FR
Newton’s Third LawNewton’s Third Law
Action-Reaction PairsAction-Reaction Pairs Both objects accelerate.Both objects accelerate.
The amount of acceleration depends on the The amount of acceleration depends on the mass of the object.mass of the object.
a Fm
Small mass Small mass more acceleration more acceleration
Large mass Large mass less acceleration less acceleration
Starter (15 minutes)Starter (15 minutes)
Get a coach workbook from the second Get a coach workbook from the second shelf of the bookshelf.shelf of the bookshelf.
Number your paper 1-16Number your paper 1-16 Answer questions 1-16 on pages 100-Answer questions 1-16 on pages 100-
104 (A,B,C,D only) you do not have to 104 (A,B,C,D only) you do not have to write the questions.write the questions.
MomentumMomentum
MomentumMomentum quantity of motionquantity of motion
p = mvp: momentum (kg ·m/s)m: mass (kg)v: velocity (m/s)m
p
v
MomentumMomentum Find the momentum of a bumper car if it has a Find the momentum of a bumper car if it has a
total mass of 280 kg and a velocity of 3.2 m/s. total mass of 280 kg and a velocity of 3.2 m/s.
GIVEN:
p = ?
m = 280 kg
v = 3.2 m/s
WORK:
p = mv
p = (280 kg)(3.2 m/s)
p = 896 kg·m/s
m
p
v
MomentumMomentum The momentum of a second bumper car is 675 The momentum of a second bumper car is 675
kg·m/s. What is its velocity if its total mass is kg·m/s. What is its velocity if its total mass is 300 kg? 300 kg?
GIVEN:
p = 675 kg·m/s
m = 300 kg
v = ?
WORK:
v = p ÷ m
v = (675 kg·m/s)÷(300 kg)
v = 2.25 m/s
m
p
v
Conservation of MomentumConservation of Momentum
Law of Conservation of MomentumLaw of Conservation of Momentum The total momentum in a group of objects doesn’t The total momentum in a group of objects doesn’t
change unless outside forces act on the objects.change unless outside forces act on the objects.
pbefore = pafter
Conservation of MomentumConservation of Momentum Elastic CollisionElastic Collision
KE is conservedKE is conserved
Inelastic CollisionInelastic Collision KE is not conservedKE is not conserved
Conservation of MomentumConservation of Momentum A 5-kg cart traveling at 4.2 m/s strikes a A 5-kg cart traveling at 4.2 m/s strikes a
stationary 2-kg cart and they connect. Find their stationary 2-kg cart and they connect. Find their speed after the collision. speed after the collision.
BEFORECart 1:m = 5 kgv = 4.2 m/s
Cart 2 :m = 2 kgv = 0 m/s
AFTERCart 1 + 2:m = 7 kgv = ?
p = 21 kg·m/s
p = 0
pbefore = 21 kg·m/s pafter = 21 kg·m/s
m
p
vv = p ÷ mv = (21 kg·m/s) ÷ (7 kg)v = 3 m/s
Conservation of MomentumConservation of Momentum A 50-kg clown is shot out of a 250-kg cannon at a A 50-kg clown is shot out of a 250-kg cannon at a
speed of 20 m/s. What is the recoil speed of the speed of 20 m/s. What is the recoil speed of the cannon? cannon?
BEFOREClown:m = 50 kgv = 0 m/s
Cannon:m = 250 kgv = 0 m/s
AFTERClown:m = 50 kgv = 20 m/s
Cannon:m = 250 kgv = ? m/s
p = 0
p = 0
pbefore = 0
p = 1000 kg·m/s
pafter = 0
p = -1000 kg·m/s
Conservation of MomentumConservation of Momentum So…now we can solve for velocity. So…now we can solve for velocity.
GIVEN:
p = -1000 kg·m/s
m = 250 kg
v = ?
WORK:
v = p ÷ m
v = (-1000 kg·m/s)÷(250 kg)
v = - 4 m/s (4 m/s backwards)
m
p
v
Universal ForcesUniversal Forces
Electromagnetic ForcesElectromagnetic Forces – are associated – are associated with charged particles. The only force to with charged particles. The only force to attract and repel.attract and repel.
Universal ForcesUniversal Forces
Nuclear ForcesNuclear Forces – act within the nucleus – act within the nucleus of an atom to hold it together, strong and of an atom to hold it together, strong and weak.weak.
Universal ForcesUniversal Forces
Gravitational ForcesGravitational Forces – attractive forces – attractive forces that act between any two masses.that act between any two masses.
““Every object in the universe attracts Every object in the universe attracts every other object.” – Newton’s Law of every other object.” – Newton’s Law of Universal Gravitation.Universal Gravitation.
Centripetal ForceCentripetal Force
Centripetal force is a center-directed force Centripetal force is a center-directed force that continuously changes the direction of an that continuously changes the direction of an object to make it move in a circle. This object to make it move in a circle. This explains how the moon and satellites stay in explains how the moon and satellites stay in orbitorbit
““The Tide Is High…”The Tide Is High…” The gravitational pull from the moon The gravitational pull from the moon
produces two bulges in the Earth’s oceans. produces two bulges in the Earth’s oceans. One is on the side closest to the moon, and One is on the side closest to the moon, and the other is on the side farthest away from the other is on the side farthest away from the moon.the moon.