32
Chapter 8 Universal Gravitation Quiz 8

Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Embed Size (px)

Citation preview

Page 1: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Chapter 8 Universal Gravitation

Quiz 8

Page 2: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Chapter 8 Objectives

• Relate Kepler's laws of planetary motion to Newton's law of universal gravitation.

• Calculate the periods and speeds of orbiting objects

• Describe the method Cavendish used to measure G and the results of knowing G

Page 3: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Chapter 8 Objectives

• Solve problems involving orbital speed and period

• Relate weightlessness to objects in free fall • Describe gravitational fields

Page 4: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Chapter 8 Objectives

• Distinguish between inertial mass and gravitational mass

• Contrast Newton's and Einstein's views about gravitation

Page 5: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Warm Up

• How do trains steer?

Page 6: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Kepler’s Laws of Planetary Motion

• 1. The paths of the planets are ellipses• 2. Imaginary line from sun to planet sweeps

out equal areas in equal times. • 3. Square of the ratio of the periods is equal

to the cube of the ratio of average distances32

B

A

B

A

r

r

T

T

Page 7: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Ellipses: Two Center of Focus (One Empty)

Page 8: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate
Page 9: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate
Page 10: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Kepler’s 3rd Law

• An asteroid revolves around the sun with a mean (average) orbital radius twice that of Earth’s. Predict the period of the asteroid in earth years.– Take note that mass doesn’t matter for orbital

period– Period = 1 complete revolution

Page 11: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Kepler’s 3rd Law

• The moon has a period of 27.3 days and has a mean distance of 3.90x105 km from the center of the earth. Predict the mean distance from Earth’s center that an artificial satellite that has a period of 1.00 day would have.– Satellites that are in geostationary orbit have this

period (TV, Weather)– Military uses satellites not in geostationary orbits

Page 12: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate
Page 13: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Universal Gravitation

• All objects which have mass exert a gravitational pull and are pulled in turn by others of mass. The force is equal to

• Where m is mass (kg) and d is distance (m) and where G = 6.67 E-11 N*m2/kg2

2d

mmGF BA

Page 14: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Universal Gravitation

• Force is then proportional to the inverse square of distance

• Distance Force– 1m 1 N– 2m ¼ N– 0.5 m 4 N

• Also note: Distance is between Center of Masses

2d

mmGF BA

Page 15: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Gravitation

• If dealing with gravitational field strength (acceleration of object) is – Large Mass = Large g– Small Radius = Large g

• Because g is gravitational field (N/kg)– All objects accelerate at same rate– Bigger mass, more force

2d

Gmg E

m

Fg

Page 16: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Universal Gravitation

• If earth began to shrink, buts its mass remained the same, what would happen to the value of g on Earth’s surface?

• If earth began to lose mass, but radius stayed the same, what would happen to the value of g on Earth’s surface?

Page 17: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate
Page 18: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Universal Gravitation

• Funny Shirt

Page 19: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Newton’s Law of Universal Gravitation

• An astronaut is on the moon.• a) Can the astronaut pick up a rock with less

effort on the moon?• b) How will the weaker gravitational force on

the moon’s surface affect the path of the rock if the astronaut throws the rock?

• C) If the astronaut drops the rock, and it lands on their toe, will it hurt more or less than on earth? Explain

Page 20: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• Satellites are constantly falling towards the planet they orbit (just as Earth is constantly falling towards the Sun)

• Inertia (horizontal velocity) + Falling (centripetal acceleration) leads to orbit

Page 21: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• To slow, Ac to large = fall to Earth

• To fast, Inertia to large = Leaves orbit

Page 22: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• Where v is speed in orbit, r is radius away from center, G is constant and m is mass of said planet.

• How does the mass of the planet and your radius influence the speed of V necessary to orbit?

r

Gmv E

Page 23: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• Calculate the speed that a satellite shot from a cannon must have in order to orbit Earth 150 km above the Earth’s surface.– Radius of Earth = 6.38 x106 meters

r

Gmv E

Page 24: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• Find the speed of Mercury and Saturn around the sun. Does it make sense that Mercury is named after a speedy messenger of the gods and Saturn is named after the father of Jupiter? Mercury is 5.79 E10 meters from the sun, Saturn 1.43 E12 meters, the mass of the sun is 1.99 E30 kg.

r

Gmv E

Page 25: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Satellites and their Speed

• The sun is considered to be a satellite of our galaxy, the Milky Way. The sun revolves around the center of the galaxy with a radius of 2.2 E20 meters. The period of one revolution is 2.5 E8 years.

• a) Find the mass of the galaxy• b) Assuming that the average star has the same

mass as the sun, find the number of stars.• c) Find the speed with which the sun moves around

the center of the galaxy.

Page 26: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Gravity in the Planets

• Explain the trend in of gravity field strength seen in the interior of planets

Page 27: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Mass revisited again

• Two types of mass– Inertial Mass : The inertial mass of an object is

measured by applying a force to the object and measuring its acceleration• Example: Put a block of ice in the back of a truck.

When you accelerate forward, the ice will slide to the back of the truck as a result of its inertial mass (resistance to acceleration)

Page 28: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Mass revisited again

• Gravitational Mass: A measurement of the attractive force between objects of mass (a scale can measure this)– Example: Drive up a hill with that ice at a constant

rate (no acceleration), yet the block slides, due to gravitational mass.

• Both masses are always in agreement and are a central point in Einstein’s general theory of relativity

Page 29: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Mass revisited again

• List three examples of examples of the effects of gravitational mass and inertial mass.

Page 30: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Mass revisited again

• Einstein said that gravity is not a force, but an effect on space itself. A mass changes the space around it. It causes space to be curved, and other bodies are accelerated by following the curve of space.

Page 31: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Mass revisited again

• Black holes: So massive, that even light can’t escape the curve

Page 32: Chapter 8 Universal Gravitation Quiz 8. Chapter 8 Objectives Relate Kepler's laws of planetary motion to Newton's law of universal gravitation. Calculate

Question

• The Earth has a radius of 149.6 million km on average from the sun. Find the following

• a) Period of the revolution of the earth around the sunb) Tangential speed of the earth around the sun

• c) Period of the rotation of the earth• d) Tangential speed of the rotation of the earth

(at the equator). The radius of the earth is 6.38 E6 m.