chapter 3. newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force...

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Page 1: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Chapter 3

Page 2: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Newton’s 2nd law2nd – an object

accelerates in the direction of the net force acting upon it

A= net force/Mass

a= Fnet/m

A force on an object is equal to the change in momentum of the object

Force = mass * accel.

F=m*a

Page 3: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Practice Your push your

friends trike with a force of 150N, his mass is 35kg the trikes is 15kg, what is the acceleration?

150N/50kg= 3m/s/s

Page 4: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

FrictionFriction is the force

that opposes motion between two opposing surfaces

Friction always acts against motion

Causes of friction – unsmooth surface, deformations, molecular attraction

Page 5: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

2 types of frictionStatic friction –

force of a resting object

Sliding or Kinetic friction - force on a moving object

Microwelds- deformations that hold cause static friction

Ever notice how it takes more force to get an object moving

                           

   

Page 6: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Air resistanceWhen drag is equal

to weight, there is no net external force on the object.

The object then falls at a constant velocity as described by Newton's first law of motion.

The constant velocity is called the terminal velocity.

This is due to the air resistance – Friction force caused when objects fall through air

Dependant upon the speed, shape, mass, and size of the object, and the density of the air.

Page 7: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 8: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Stuff fallshttp://www.youtube.

com/watch?v=5C5_dOEyAfk

http://nssdc.gsfc.nasa.gov/planetary/image/featherdrop_sound.mov

All objects near the surface of the earth accelerate at a rate of 9.8m/s/s

Objects of different masses will fall at the same rate regardless of their mass

Page 9: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 10: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Gravitational accelertionMore force acts upon

a more massive object, but its larger mass requires more force to accelerate.

There is a myth about Galileo dropping canon balls off the leaning tower of Pisa to prove this.

Page 11: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 12: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Gravitational accelerationVelocity of a freefalling object can be found

with the formula v= g*tWhere gravities acceleration is 9.8m/s/s

How can you find falling distanceD= ½ g *t2

Page 13: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

CentripetalCentripetal

acceleration: acceleration toward the center of a curved path

Centripetal means center seeking- it is merely a net force

Page 14: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Centripetal ex.

As a car makes a turn, the force of friction acting upon the turned wheels of the car provide the centripetal force required for circular motion.

As a bucket of water is tied to a string and spun in a circle, the force of tension acting upon the bucket provides the centripetal force required for circular motion

As the moon orbits the Earth, the force of gravity acting upon the moon provides the centripetal force required for circular motion – p.s. the moon is a banana

Page 15: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

WeightWeight – The

measure of the force of gravity on a body.

On earth your weight in Newtons (N) is equal to your mass in kg times gravity’s acceleration (9.8m/s2)

W= m * g

Page 16: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

WeightlessnessWeightlessness is sensation experienced

when there are no external objects touching one's body and exerting a push or pull

Page 17: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Astronauts on the orbiting space shuttle are weightless because..

a. there is no gravity in space and they do not weigh anything.

b. space is a vacuum and there is no gravity in a vacuum.

c.  space is a vacuum and there is no air resistance in a vacuum.

d. the astronauts are far from earth's surface at a location where gravitation has a minimal effect.

Page 18: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Freefallin’Orbit is a state of

constant freefall – the Earth’s surface is falling away at the same rate of orbit

400 km above the earth's surface, the the value of g will have been reduced from 9.8 m/s/s (at earth's surface) to approximately 8.7 m/s/s. About 10% less than the surface

Page 19: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Projectile motionProjectile motion:

Anything that has horizontal motion is a projectile

Horizontal and vertical motion act independently of one another-

Projectiles follow a path called a trajectory

Page 20: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 21: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

So a bullet dropped and a bullet fired from the same height will hit the ground at the same time.

Page 22: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 23: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Newton’s 3rd lawFor every action

(force) in nature there is an equal and opposite reaction.

Force pairs: Action and reaction forces do not act on the same object.

What would happen if they did?

Page 24: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Many reaction forces are not noticed due to other forces or smaller accelerations.Introduction to Rocket Performance - Level 3 - Jump Animation

Page 25: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object
Page 26: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

MomentumMomentum:

property of a moving object based on its velocity and mass.

p = mvkg x m/s – label

Page 27: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Momentum is conservedLaw of

Conservation of Momentum: Momentum may be exchanged but the total amount of momentum remains the same.

Page 28: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

In a game of pool where is the momentum lost

Page 29: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

PracticeA scooter and a big

red truck, both moving at 20m/s. Which has more momentum.

Mass of red truck 3000kg

Mass of scooter 8kgMomentum of

truck:of Scooter:

Page 30: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Force and momentumObjects with

momentum can apply force to other objects when they strike each other

F=mvf – mvi/t

This is a formula combining the 2nd and 3rd laws

A baseball strikes your glove with a velocity of 49m/s, its mass is .145kg. The ball comes to a stop in .05s. What force is applied?

Page 31: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

Artificial Satellite vs. Natural SatelliteSputnik: 1957

Russian (October 4th) “Fellow Traveler or Satellite”

What do we use satellites for?

Weather TV Communications

Science and Research

Page 32: Chapter 3. Newton’s 2 nd law 2 nd – an object accelerates in the direction of the net force acting upon it A= net force/Mass a= Fnet/m A force on an object

SatellitesHow many satellites

currently orbit the earth?

Geosynchronous Satellites: Orbital speed matches the earth’s rotation

Where? 35,790 km above the equator.

International Space Station: 390 km