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Chapter 2. Newton's First Law of Motion. - Inertia. 1. ARISTOTLE ON MOTION. Aristotle attempted to understand motion by classification . Two Classes: Natural and Violent. Natural. Natural motion depended on nature of the object. Examples: A rocks falls . Smoke rises.
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Chapter 2 Newton's First Law of Motion - Inertia
1. ARISTOTLE ON MOTION Aristotle attempted to understand motion by classification. Two Classes: Natural and Violent
Natural Natural motion depended on nature of the object. Examples: A rocks falls Smoke rises
The falling speed of an object was supposed to be proportional to its weight. Natural motion could be circular (perfect objects in perfect motion with no end).
Violent Pushing or pulling forces imposed motion. Some motions were difficult to understand. Example: the flight of an arrow There was a normal state of rest except for celestial bodies.
Aristotle was unquestioned for 2000 years. Most thought that the Earth was the center of everything for it was in its normal state. Little did they know that it was Texas No one could imagine a force that could move it.
2. COPERNICUS ANDTHE MOVING EARTH Sun was center, not earth. He was hesitant to publish because he didn't really believe it either. De Revolutionibus reached him on the day he died, May 24, 1543.
3. GALILEO AND THE LEANING TOWER 17th Century scientist who supported Copernicus. He refuted many of Aristotle's ideas. Worked on falling object problem - used experiment.
4. GALILEO'S INCLINED PLANES Knocked down Aristotle's push or pull ideas. Rest was not a natural state. The concept of inertia was introduced. Galileo is sometimes referred to as the “father of experimentation.”
He tested with planes. Demo - Ball and Incline Plane The change in speed depended on the slope of the incline.
5. NEWTON’S FIRST LAW OF MOTION Newton finished the overthrow of Aristotelian ideas. Law 1 (Law of Inertia) Every object continues in its state of rest, or of uniform motion in a straight line, unless it is compelled to change that state by forces impressed upon it. “If you leave an object alone, it has constant velocity.”
Demonstrations Demo - Weight and String Demo - Card, Cup, and Coin Demo - Swinging Rocks Demo - Coins on Elbow Demo - Table Setting Demo - Bottle, Hoop, and Chalk Demo – Lead Brick and Hammer
m m m m m m 6. NET FORCE A force or a combination of forces produces changes in motion (accelerations). 10 N = 20 N 10 N = 10 N 10 N 0 N = 20 N 10 N 10 N
7. THE EQUILIBRIUM RULE Scales pushing up Examples of Mechanical Equilibrium: Normal up Computer setting on a table Weight down Weighing yourself on a set of scales Hanging from a tree Tree pulling up Weight down Car parked on an incline Normal Friction Weight down Weight down
Scales pushing up Normal up Weight down Weight down 8. SUPPORT FORCE In the first example of mechanical equilibrium the table supplied a force upward that was called the normal force. It is a support force. Consider the second example of mechanical equilibrium. The scales supply a support force on the man.
9. EQUILIBRIUM OF MOVING THINGS Equilibrium is a state of no change. If an object moves in a straight line with no change in speed, it is in equilibrium. Examples: Driving at constant velocity Normal up Air resistance Air Resistance Force from road Weight down Terminal velocity in parachuting Weight down
10. THE MOVING EARTH It is hard to detect the motion of the earth because we are moving with it. Early science could not predict large enough forces to move the earth. Can Hewitt’s bird drop down and catch the worm if the Earth moves at 30 km/s? Demo - Cart and Ball Launcher Video– Snowmobile and Flare
Which person below is most highly recognized for proposing a heliocentric universe? (a) Aristotle (b) Newton (c) Galileo (d) Copernicus
If an object weighs 10 lb, what must the air resistance force be if the object is falling and has reached terminal velocity? (a) 10 lb (b) 32 lb (c) there is no way of telling without knowing what the value of the terminal velocity is
Newton's concept of motion said that the natural state of an object was (a) constant velocity (b) constant acceleration (c) constant net force