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 In order to make an object at rest move, you need to apply a push or a pull, otherwise known as a force.  A force can make an object:  Speed up 

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Presentation on theme: " In order to make an object at rest move, you need to apply a push or a pull, otherwise known as a force.  A force can make an object:  Speed up "— Presentation transcript:

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2  In order to make an object at rest move, you need to apply a push or a pull, otherwise known as a force.  A force can make an object:  Speed up  Slow down  Change direction …AKA change velocity or accelerate

3 Force: any influence that tends to accelerate an object.  Forces produce accelerations  Ex: a push or a pull  SI unit: Newtons (N)

4 Newton’s 1 st Law of Motion: An object at rest will stay at rest and an object in motion will stay in motion …. Unless acting on by an outside force !!! AKA: the Law of Inertia  Ex: An object moving in space will keep moving at a constant speed

5 Inertia: the property of an object to resist a change in motion.  Things tend to keep doing what they’re already doing.  SI Unit: kilograms (kg)  Ex: you keep moving when a Marta train stops b/c you have inertia

6  Objects in a state of rest, stays at rest.  Ex: pulling the tablecloth out from under a table full of plates and cups  Objects in motion, stay in motion.  Only if moving at a constant velocity in a straight line.  Ex: A car you are sitting in stops, but you keep moving forward (this is why we wear seatbelts)

7 Mass: the amount of matter present in an object  The more mass, the greater the inertia…and the greater the force it takes to change the state of motion.  Mass remains the same wherever you are  SI units: kilograms (kg)  Ex: your mass is 10 kg on Earth and on the moon

8 Why is it more difficult to stop a rolling car than a rolling toy car? The car has more mass and therefore more inertia. The inertia an object has, the more is needed to change its state of motion (liking making something stop).

9 Weight: the force of gravity on an object’s mass  Ex: your weight on Earth is 100 N, but on the moon it is 16 N  SI unit: Newtons (N) W = mg  Equation: W = mg  W = weight (N)  m = mass (kg)  g = acceleration due to gravity (10m/s 2 )

10  Mass and weight are used interchangeably in everyday language, but they are NOT the same thing in physics!  Weight varies with location, based on gravity.  Mass is the same everywhere; weight is not.

11 A ball has a mass of 10 kg on Earth. Will its mass be more or less on the moon? Neither, the mass will be the same in both locations because the mass of an object does not change. What about the weight? The ball will weigh more on the Earth than the moon because there is more gravity on Earth.

12 A girl has a mass of 25 kg. What is her weight on Earth? W = ? m = 25 kg g = 10 m/s 2 W = mg W = (25)(10) W = 250 N

13  A force is a vector  It takes into account direction Net force: the combination of all forces acting on an object.  It is the net force that changes an object’s state of motion.  SI Unit: Newtons (N)  Ex: If you push on a cart with 10 N of force and someone else pushes in the opposite direction with 4 N, the net force is 6 N.

14  If an object is resting on the table, the table is pushing on it with the same force that the book is pushing on the table, the object is in equilibrium. Equilibrium: when the net force is equal to zero.  An object in equilibrium has only inertia, no force acting on it and is moving at a constant velocity or not moving at all  Ex: You push on the wall with 10 N of force, the wall pushes on you with 10 N of force to equal 0 N.

15 A girl pushes a cart with a force of 10 N, however her mischievous friend pushes the same cart in the opposite direction with 5 N of force. What is the net force? Since they are going in opposite directions, you subtract the forces to find the net force. 10 N – 5 N = 5N

16 A hockey player hits a hockey puck across the ice. 10 seconds after he hits it and it is still moving down the ice, is the puck in equilibrium? Yes! Even though it is still moving, there is no net force being exerted on it, so it is moving at a constant velocity and only inertia is allowing it to keep moving.

17  If a force is applied to an object at rest, it starts to move  The object accelerates because it changed motion (from rest to movement)  Once it is moving at a CONSTANT VELOCITY (on a frictionless surface) no force is needed.  Because of INERTIA!

18  To increase the acceleration of the object, more force needs to be applied  Net force is directly proportional to acceleration  2F = 2a  3F = 3a

19  As the mass increases, the acceleration decreases if the same amount of force is applied to the object  Mass resists acceleration  Mass and acceleration are inversely proportional  2 m, ½a  ½ m, 2a  10 m, 1/10a  1/10 m, 10a

20 Newton’s 2 nd Law: The acceleration produced by a net force on an object is directly proportional to the magnitude of the net force, is in the same direction as the net force, and is inversely proportional to the mass of the object. Car Test Dummies Video Clip

21  Forces produce accelerations  Ex: The harder you push something, the faster it goes F = ma  Equation: F = ma  F = force (N)  m = mass (kg)  a = acceleration (m/s 2 )

22 A boy pushes on a 10 kg cart with a force of 50 N. What is the acceleration of the cart? a = ? F = 50 N m = 10 kg F = ma 50 = (10)a a = 50/10 a = 5 m/s 2

23 A car is set on cruise control and moving at a constant 50 m/s headed east. If the car’s mass is 1000 kg, what is its acceleration? Because the car is not CHANGING its velocity, the acceleration is zero What is the force? F = ? m = 1000 kg a = 0 m/s 2 F = ma F = 1000 (0) F = 0 N

24  Everything in nature comes in pairs.  Forces also always come in pairs.  A force is not just a push or pull, but a part of an interaction between one thing and another.  In an interaction between objects, there are a pair of forces (one acting on each object).

25 Does a stick of dynamite contain force? No. Force is not something an object has, like mass. Force is an interaction between two objects. An object may have the capability to exert a force on another object, but it cannot possess force as a thing in itself.

26 Newton’s 3 rd Law of Motion: Whenever one object exerts a force on a second object, the second object exerts an equal and opposite force on the first object.  aka The Law of Action and Reaction  For every action, there is an equal and opposite reaction.  Ex: You hit the wall, but the wall is hitting you back (hence why it hurts)

27  One force is the action force and the other force is the reaction force.  Neither coexists without the other.  You can’t touch something without being touched.

28 Earth and the moon are “connected” to each other by a gravitational force. Is Earth pulling on the moon, or is the moon pulling on Earth? Both! They are part of the same interaction. They pull on each other in an action-reaction pair.

29 Identify the action and reaction pair of forces for the case of a bat interacting with a ball. The bat pushes on the ball and the ball pushes on the bat.

30  Action: Object A exerts a force on object B  Reaction: Object B exerts a force on object A  The forces are equal and in opposite directions, even if the masses are very different.

31  According to Newton’s 2 nd law ( F = ma), if mass is not proportional to the pair of forces, neither is the acceleration…but the masses are still inversely proportional to the accelerations. F = F m a = m a

32 Can you identify the action and reaction forces of an object falling in a vacuum of outer space? The interaction is the gravitational attraction between the falling object and another object in space, possibly a distant planet. So the planet pulls down the object (action) while the object pulls up on the planet (reaction).

33 According to Newton’s 3 rd law of motion, the action and reaction forces are equal. Does that mean that the planet is actually moving towards the object? Yes. The same thing happens when you jump on Earth; the Earth moves towards you. But in both cases the mass of the planet is so large compared to the mass of the object/person, the acceleration would be infinitesimally small, almost zero. That’s why we don’t feel Earth move to one side every time a person jumps.


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