1. Jones Physical Science

2. Friction  What is friction?  Friction: the unbalanced force that acts against an object’s direction of motion  Why does friction occur?  The surface of any object is rough and sticks to other surfaces that are also rough  How does friction affect motion?  It opposes any applied force  How does a car keep moving?

3. Two types of Friction  Static friction  The friction between stationary (nonmoving) surfaces  Kinetic friction  The friction between moving surfaces  Can be either sliding friction or rolling friction  Sliding friction: when two objects slide past each other  Rolling friction: when a round object rolls over a flat surface

4. Friction  Other than the friction caused by the tires coming in contact with the ground, what other friction is there to oppose the motion of the car?  Fluid friction  Friction caused by an object moving through a fluid, such as air  What can car companies do to take care of this potential problem?

5. Positive friction  Without friction, the tires of a car would not be able to push against the ground and move the car forward.  You are using friction right now to push ink or lead on your paper so much to leave a mark.  Without friction, you would slip and fall when you tried to walk.

6. Positive friction  How can positive friction be increased?  Make surfaces rougher  Increase the force pushing the surfaces together

7. Negative friction  How can negative friction be decreased?  Use lubricants such as motor oil, wax, and grease  Replace sliding friction with rolling friction  Rolling friction is usually less than sliding  Make the surfaces smoother

8. Newton’s Laws of Motion  Sir Isaac Newton established three laws that describe the relationship between motion and force.

9. Newton’s First Law  An object at rest remains at rest and an object in motion maintains its velocity unless it experiences an unbalanced force.  Inertia is the resistance in change of motion.  Inertia is related to mass  An object with a small mass has less inertia, and it is easier to change its motion  An object with a large mass has more inertia, and it requires more force to change its motion

10. Newton’s First Law  Explain the function of a car seat or a seat belt in terms of mass and inertia.  Is the person in motion if the car is in motion? YES  If the car meets an unbalanced force, what will happen to the person if there is no unbalanced force acting on the person as well as the car?

11. Newton’s Second Law  The unbalanced force acting on an object equals the object’s mass times its acceleration.  Force = mass x acceleration (F=ma)  Page 349 Fig 3  Empty grocery car versus full grocery cart  Imagine pushing both carts with the SAME force  Which one will be moved farther? Why?

12. Newton’s Second Law  Practice problems  Page 351 #1-3 in your notes

13. Gravity  All matter is affected by gravity  Gravitational force increases as mass increases  Gravitation force decreases as distance increases

14. Free-fallin’  When gravity is the only force acting on an object, it is said to be in free-fall.  The free-fall acceleration towards the center of Earth of ANY object is 9.8 m/s 2

15. What is the difference between mass and weight?  Mass – a measure of the amount of matter in an object  Weight – dependent on gravity; equal to an object’s mass times free-fall acceleration  Unit is Newtons (N)  Weight = mass x 9.8 m/s 2

16. Can weight influence the shape of living things?  YES!  Large, land animals must have strong skeletons to support their mass against the force of gravity  Marine life does not require strong skeletons because it can drift due to the downward force of gravity being balanced by the upward force of the water.

17. What happens to objects moving through Earth’s atmosphere?  Both air resistance and gravity act on the object.  Velocity becomes constant when the force of air resistance is equal to the gravitational force on the object.  The object will stop accelerating and will reach its maximum velocity, also called terminal velocity.

18. Objects In Space…  Objects in space are in free fall (there is no air resistance)  Weight is a gravitational force that depends on the masses of objects and the distance between them  Therefore, it is impossible to be weightless anywhere in the universe.

19. Objects In Space…  Orbiting objects are also in free fall  What causes orbiting?  Orbiting: when an object is traveling in a circular path around another object  Two motions are responsible for creating an orbit:  Path of the object (Moon’s path, direction of spaceship)  Earth’s gravitational pull  When the forward motion combines with free fall, the object follows the curve of the Earth’s surface.

20. Projectile Motion  Projectile motion: the curved path an object follows when thrown, launched, or otherwise projected near the surface of the Earth  Two independent components:  Horizontal motion  Vertical motion  The two do not affect each other, but combine to form a curved path  P 358 Figure 13

21. Projectile Motion  First component: Horizontal motion  A force is exerted on an object to make it go horizontal  Second component: Vertical motion  Gravity pulls the object downward  Putting these together result in a curved path  Why do archers aim above the bull’s eye on a target?

22. Newton’s Third Law  For every action force, there is an equal and opposite reaction force.  Also called the “law of action and reaction”

23. Forces always occur in pairs  Whenever a force is exerted, another force occurs that is equal in size and opposite in direction.  Even when there is no motion  Example:  Your weight pushing down on the chair while sitting: action force  The chair pushing back up with a force equal to your weight: reaction force

24. Force pairs do not act on the same object!  P 361 Fig 16  Action force: the swimmer pushing the water backward  Reaction force: the water pushing the swimmer forward

25. Momentum  Momentum: a property of all moving objects, which is equal to the product of the mass and the velocity of the object.  Momentum (p) = mass (m) x velocity (v)  Practice problems Page 363 #1-2

26. Momentum is dependent on mass  Objects with less mass have less momentum  Objects with more mass have more momentum  Momentum also has direction –  An object’s momentum is in the same direction as its velocity.

27.  How can momentum of an object be changed?  Apply a force to the object  The object collides with another object  Transferring the momentum from one object to another Changing momentum

28.  By applying force  Happens when you force an object to change its motion  Extending the time needed to change the momentum lessens the force  For example, moving in the direction of the motion after landing a pole-vault, high-jump, or gymnastics trick, extends the time of the momentum change, which results in the impact force decreasing.

29. Changing momentum  When two objects collide, momentum is conserved (total amount of momentum does not increase or decrease).  Some momentum may be transferred from one object to another, such as in the game of pool.  Fig 21 on Page 365  The rocket pushes gases downward/backward toward the surface of the Earth  The gases push the rocket upward/forward toward the sky in an equal amount.