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Units 14-18 are covered

Learn about Galileo Galilei's groundbreaking observations that challenged ancient beliefs about the Universe, and Isaac Newton's laws of motion that revolutionized our understanding of how objects move. Discover how mass and inertia play a role in motion, and how forces affect acceleration. Explore Newton's second and third laws, and understand the concept of orbital motion and gravity.

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Units 14-18 are covered

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  1. Units 14-18 are covered

  2. Using a Dutch-designed telescope that he built himself, he made several startling observations that disproved ancient thinking about the Universe Found sunspots, showing that the Sun was not a perfect sphere Found craters on the Moon, showing that the Moon was not a perfect sphere Discovered four moons of Jupiter, showing that not everything revolved around the Sun Observed the rings of Saturn Observed that Venus passed through all phases, just as the Moon does. In a geocentric model, the phases of Venus were limited to crescents. One of the principal founders of the experimental method for studying scientific problems. Galileo Galilei (1564-1642)

  3. Isaac Newton (1642-1727) • Isaac Newton described the fundamental laws covering the motion of bodies • Had to invent his own mathematics (Calculus) to do it! • His work is used even today in calculating everything from how fast a car stops when you apply the brakes, to how much rocket fuel to use to get to Saturn! • And he did most of it before his 24th birthday…

  4. Mass and Inertia • Mass is described by the amount of matter an object contains. • This is different from weight – weight requires gravity or some other force to exist! • Ex: while swimming, your weight may feel less because the body floats a little. Your mass, however, stays the same! • Inertia is simply the tendency of mass to stay in motion

  5. The Law of Inertia • Newton’s First Law is sometimes called the Law of Inertia: • A body continues in a state of rest, or in uniform motion in a straight line at a constant speed, unless made to change that state by forces acting on it • Or, more simply, a body maintains the same velocity unless forces act on it • A ball rolling along a flat, frictionless surface will keep going in the same direction at the same speed, unless something pushes or pulls on it • Gravity!

  6. Another View of Newton’s First Law • If an object’s velocity is changing, there must be forces present! • Dropping a ball • Applying the brakes in a car • If an object’s velocity is not changing, either there are no forces acting on it, or the forces are balanced and cancel each other out • Hold a ball out in your hand, and note that it is not moving • Force of gravity (downward) is balanced by the force your hand applies (upward)!

  7. Tie a string to a ball and swing it around your head Law of inertia says that the ball should go in a straight line Ball goes in a circle – there must be forces! Where’s the force? It’s the tension in the string that is changing the ball’s velocity If the string breaks, the ball will move off in a straight line (while falling to the ground) Circular Motion

  8. The term acceleration is used to describe the change in a body’s velocity over time Stepping on the gas pedal of a car accelerates the car – it increases the speed Stepping on the brakes decelerates a car – it decreases the speed A change in an object’s direction of motion is also acceleration Turning the steering wheel of a car makes the car go left or right – this is an acceleration! Forces must be present if acceleration is occurring Acceleration

  9. The force (F) acting on an object equals the product of its acceleration (a) and its mass (m) F = m  a We can rearrange this to be: a = F/m For an object with a large mass, the acceleration will be small for a given force If the mass is small, the same force will result in a larger acceleration! Though simple, this expression can be used to calculate everything from how hard to hit the brakes to how much fuel is needed to go to the Moon! Newton’s Second Law

  10. Newton’s Third Law • When two bodies interact, they create equal and opposite forces on each other • If two skateboarders have the same mass, and one pushes on the other, they both move away from the center at the same speed • If one skateboarder has more mass than the other, the same push will send the smaller person off at a higher speed, and the larger one off in the opposite direction at a smaller speed • Why? This works for planets, too!

  11. Astronauts in orbit around the Earth are said to be in free fall, a weightless state. Are they falling? Yes! Imagine a cannon on top of a mountain that fires a cannonball parallel to the ground The cannonball leaves the cannon and is pulled toward the ground by gravity If the ball leaves the cannon with a slow velocity, it falls to the ground near the mountain If the cannonball has a higher velocity, if falls farther from the mountain. What if we gave the cannonball a very large velocity, so large that it “misses” the Earth? The cannonball would be in orbit around the Earth, and it would be falling! Orbital Motion and Gravity

  12. Every mass exerts a force of attraction on every other mass. The strength of the force is proportional to the product of the masses divided by the square of the distance between them Simply put, everything pulls on everything else Larger masses have a greater pull Objects close together pull more on each other than objects farther apart This is true everywhere, and for all objects The Sun and the planets exert a gravitational force on each other You exert a gravitational force on other people in the room! Newton’s Universal Law of Gravitation

  13. Objects on the Moon weigh less than objects on Earth This is because surface gravity is less The Moon has less mass than the Earth, so the gravitational force is less We let the letter g represent surface gravity, or the acceleration of a body due to gravity F = mg On Earth, g = 9.8 m/s2 g on the Moon is around 1/6 as much as on the Earth! Surface Gravity

  14. Centripetal Force • If we tie a mass to a string and swing the mass around in a circle, some force is required to keep the mass from flying off in a straight line • This is a centripetal force, a force directed towards the center of the system • The tension in the string provides this force. • Newton determined that this force can be described by the following equation:

  15. Orbits • Orbital velocity: We can use this expression to determine the orbital velocity (V) of a small mass orbiting a distance d from the center of a much larger mass (M)

  16. Calculating Escape Velocity • From Newton’s laws of motion and gravity, we can calculate the velocity necessary for an object to have in order to escape from a planet, called the escape velocity

  17. What Escape Velocity Means • If an object, say a rocket, is launched with a velocity less than the escape velocity, it will eventually return to Earth • If the rocket achieves a speed higher than the escape velocity, it will leave the Earth, and will not return!

  18. Sun is approximately ...... than Earth • a. 100x wider and 300 000x as massive as; • b. 10000x wider and 100x as massive as; • c. 10x wider and 300x as massive as; • d. 100000000x wider and 10x as massive as.

  19. When the Northern Hemisphere experiences summer the Southern Hemisphere experiences • a. spring; • b. summer; • c. fall; • d. winter.

  20. The size of the galaxy is about ....... times the size of the Solar System. • a. 10 • b. 100 • c. 1000 • d. 100 000 000

  21. If an event were to take place on the Sun, how long would it take to reach us? • a. 8 minutes • b. 11 hours • c. 1 second • d. 10 days

  22. If the Sun is located at one focus of Earth’s elliptical orbit, what is the other focus? • A. Earth • B. The Moon • C. Nothing • D. This is a trick question. An ellipse has only one focus

  23. The time it takes a planet to complete one full orbital revolution is known as its • A. Period • B. frequency • C. orbital domain • D. Velocity

  24. Kepler’s law can be expressed mathematically as • A. P=A • B. P=A2 • C. P2=A3 • D. P3=A2

  25. Suppose a planet has a semimajor axis of 4AU. How long does it take for this planet to orbit once around the Sun in terms of Earth years • A. 2 Earth-years • B. 4 Earth-years • C. 8 Earth-years • D. 16 Earth-years

  26. Sun is approximately ...... than Earth • a. 100x wider and 300 000x as massive as; • b. 10000x wider and 100x as massive as; • c. 10x wider and 300x as massive as; • d. 100000000x wider and 10x as massive as.

  27. When the Northern Hemisphere experiences summer the Southern Hemisphere experiences • a. spring; • b. summer; • c. fall; • d. winter.

  28. The size of the galaxy is about ....... times the size of the Solar System. • a. 10 • b. 100 • c. 1000 • d. 100 000 000

  29. If an event were to take place on the Sun, how long would it take to reach us? • a. 8 minutes • b. 11 hours • c. 1 second • d. 10 days

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