1. Physics 2 Randy Hedlund South High School
Astronomy 2014
Physics 2
Randy Hedlund South High School

2. 12/1 Can you name all the planets? What is the largest planet?
What are ways that planets are different? (i.e what are there characteristics?
If you could visit one planet which one would you visit and why

3. Activity : How did the solar system form critical reading.

4. 12/2 1. Explain in your own words how the solar system formed.
2. What 2 things causes the force of gravity to increase between two objects?
3. Create a list of 2-3 questions you have about the universe.
Agenda : tour the solar system, ACT practice
Asteroid impact versus gradual extinction
Gravitational attraction between gas and dust

5. .the rocky and cratered surface of Mercury resembles our own Moon °F (-184°C) (on the side away from the sun) to about 800°

7. Mercury One rotation takes 59 days. One year is 88 days.
It has no moon or rings.
Mercury is the closest planet to the sun.
It looks a lot like our moon.
Click here to
learn about Mercury.

8. Venus One rotation takes 243 days. One year is 224.7 days.
It has no moon or rings.
Venus is the second planet from the sun.
It is as dry as a desert and hotter than an oven..
Click here to
learn more about
Venus.

9. Venus – the second planet
Very active volcanic activity
Greenhouse effect - Venus' thick, toxic atmosphere traps heat in a runaway 'greenhouse effect.' The scorched world has temperatures hot enough to melt lead.
464 °C (867°F)

10. Impact crater on Venus – it has relatively few, due to the young surface

11. Earth One rotation takes 24 hours. One year is 365 1/4 days.
It has 1 moon and no rings.
It is the third planet from the sun.
Earth is mostly covered with water.
Click here to learn more about Earth.

12. Earth – the only planet with liquid water
How does this make it hospitable?
Goldilocks zone,

13. MARS One rotation takes 24.5 hours. One year is 687 days.
It has 2 moons and no rings.
It is the fourth planet from the sun and the last of the inner planets.
Mars looks red because of rusty iron in its soil and red dust in its air.
Click here to learn more about Mars.

14. Mars – 4th planet
Mars's thin atmosphere, visible on the horizon in this low-orbit photo.
Photo of microscopic rock forms indicating past signs of water, taken by Opportunity

15. Jupiter One rotation takes 9.8 hours. One year is 12 earth years.
It has at least 16 moons and 2 rings.
It is the fifth planet from the sun and the first gas planet.
It has a great red spot of swirling gas.
Click here to
learn more about
Jupiter.

16. The clouds are arranged in light-colored areas called zones and darker regions called belts that circle the planet parallel to the equator
Theoretical models indicate that if Jupiter had much more mass than it does at present, the planet would shrink

17. Europa – moon of Jupiter – hydrothermal vent

18. Saturn One rotation takes 10.7 hours. One year is 29.5 Earth years.
It has at least 17 moons and many rings.
Saturn is the sixth planet from the sun and the second gas planet.
Saturn’s rings are made of ice, rock, and dust.
Click here to
learn more about
Saturn.

19. This captivating natural color view of the planet Saturn was created from images collected shortly after Cassini began its extended Equinox Mission in July 2008.
213,000 km (from 1.14 to 3.53 times Saturn's equatorial radius), and they are thin, with a thickness as small as 100m (astrophysicsspectator.com/topics/planets/SaturnRings.html)

20. Uranus One rotation takes 17 hours. One year is 84 earth years.
It has at least 15 moons and 10 rings.
Uranus is the seventh planet from the sun and the third gas planet.
Uranus seems to rotate on its side.
Click here to
learn more about
Uranus.

21. Uranus's axis of rotation lies on its side with respect to the plane of the Solar System, with an axial tilt of degrees
Why Uranus's internal temperature is so low is still not understood

22. Neptune One rotation takes 16 hours. One year is 165 earth years.
It has 8 moons and 4 rings.
It is the eighth planet from the sun and the last gas planet.
Neptune is blue-green.
Neptune
Click here to learn more about Neptune.

23. The blue clouds of Neptune are mostly frozen methane, the main chemical in natural gas -- a fuel for heating and cooking on Earth.

24. Formation of the solar system
Dust attracted by gravity
Contracted gases began swirling
Protostar formed when hot enough for fusion (10 million degrees)
Mass condensed into planets

25. Future Topics create a summary of these topics and cite your sources for extra credit
Hubble deep field
How far back can we see?
Can plants grow on other planets?
What causes the rings on planets to form?
What is Kepler- 22

26. 12/3 Have you taken the ACT? Do you plan to take the ACT?
Compare and contrast the terrestrial planets with the gas giants.
How does the distance from the sun affect the period of revolution?
Agenda
ACT asteroid impact theory versus gradual extinction theory

27. Science is a process of understanding and comprehending

28. ACT formats
• Data Representation: This format presents students with graphic and tabular materials similar to those found in science journals and texts. The test questions associated with this format measure knowledge and skills such as graph reading, interpretation of scatterplots, and interpretation of information presented in tables, diagrams, and figures.
• Research Summaries: This format provides students with descriptions of one experiment or of several related experiments. The test questions focus on the design of the experiments and the interpretation of results.
• Conflicting Viewpoints: This format presents students with several hypotheses or views that are mutually inconsistent owing to different premises, incomplete data, or differing interpretations of data. The passage may contain illustrations, charts, graphs, tables, diagrams, or figures. The test questions measure students’ knowledge and skills in understanding, analyzing, and comparing alternative viewpoints or hypotheses.

29. Understanding: Identify and evaluate scientific concepts, assumptions, and components of an experimental design or process; identify and evaluate data presented in graphs, figures, or tables; translate given data into an alternate form.
• Analyzing: Process information needed to draw conclusions or formulate hypotheses;
determine whether information provided supports a given hypothesis or conclusion;
evaluate, compare, and contrast experimental designs or viewpoints; specify alternative ways of testing hypotheses or viewpoints.
• Generalizing: Extend information given to a broader or different context; generate a model consistent with given information; develop new procedures to gain new information;
usegiven information to predict outcomes.

30. Advise from other students
Scan everything first – get the jist
Read questions
Read article

31. 17. Astronomers recently estimated that only 3% of
asteroids with orbits that intersect Earth’s have been
identified. This finding adds support to the asteroid impact
theory by:
A. increasing the likelihood of past Earth-asteroid
collisions.
B. showing how little astronomers know about
asteroids.
C. proving that iridium-rich asteroids are common in
the solar system.
D. showing that many asteroids

32. 17. Astronomers recently estimated that only 3% of
asteroids with orbits that intersect Earth’s have been
identified. This finding adds support to the asteroid impact
theory by:
A. increasing the likelihood of past Earth-asteroid
collisions.
B. showing how little astronomers know about
asteroids.
C. proving that iridium-rich asteroids are common in
the solar system.
D. showing that many asteroids

33. 18. A geologist examines a sedimentary rock layer from
the Mesozoic-Cenozoic boundary. According to the
asteroid-impact theory, the geologist should not expect
to find:
a. a high concentration of iridium.
b. a high concentration of soot particles.
c. evidence of great volcanic activity.
d. fossilized plant remains.

34. 18. A geologist examines a sedimentary rock layer from
the Mesozoic-Cenozoic boundary. According to the
asteroid-impact theory, the geologist should not expect
to find:
a. a high concentration of iridium.
b. a high concentration of soot particles.
c. evidence of great volcanic activity.
d. fossilized plant remains.

35. 19. What do supporters of the asteroid-impact theory
assume about the fires started by the white-hot asteroid
fragments?
A. They spread quickly and were wide ranging.
B. They removed carbon dioxide from the atmosphere,
causing a global cooling.
C. They burned the vegetation, limiting the food
supply.
D. They produced high levels of carbon dioxide,
causing a global warming.

36. 19. What do supporters of the asteroid-impact theory
assume about the fires started by the white-hot asteroid
fragments?
A. They spread quickly and were wide ranging.
B. They removed carbon dioxide from the atmosphere,
causing a global cooling.
C. They burned the vegetation, limiting the food
supply.
D. They produced high levels of carbon dioxide,
causing a global warming.

37. 20. Both theories presented in the passage cite which of the following factors as contributing directly to the dinosaurs’ extinction?
A. High levels of soot and volcanic ash
b. High concentrations of iridium
c. Global temperature change
d. Increased amounts of carbon dioxide introduced into the atmosphere

38. 20. Both theories presented in the passage cite which of the following factors as contributing directly to the dinosaurs’ extinction?
A. High levels of soot and volcanic ash
b. High concentrations of iridium
C. Global temperature change
d. Increased amounts of carbon dioxide introduced into the atmosphere

39. 21. Mass extinctions throughout history often occur in conjunction with drops in the sea level. What would proponents of the gradual-extinction theory have to demonstrate to tie those facts together? A. Mass extinctions and drops in the sea level are both caused by increased volcanic activity. B. The greenhouse effect causes lowering of the sea level as well as gradual mass extinctions. C. With less water available, fires run rampant and destroy the food supply. D. Drops in the sea level and mass extinctions are caused by changes in climate

40. 21. Mass extinctions throughout history often occur in conjunction with drops in the sea level. What would proponents of the gradual-extinction theory have to demonstrate to tie those facts together? A. Mass extinctions and drops in the sea level are both caused by increased volcanic activity. B. The greenhouse effect causes lowering of the sea level as well as gradual mass extinctions. C. With less water available, fires run rampant and destroy the food supply. D. Drops in the sea level and mass extinctions are caused by changes in climate

41. 22. After examining the 250-million-year fossil record, 2 paleontologists have uncovered evidence suggesting that the rate of species extinctions peaks every 26 million years. Supporters of the asteroid-impact theory would most likely favor which of the following explanations to account for this finding? a. Some massive object periodically disrupts the solar system, causing comets and asteroids to enter the inner solar system. b. The tilt of Earth’s axis changes every 26 million years, causing long-term climatic changes that lead to mass-extinction episodes. c. Earth’s orbit becomes more elliptical every 26 million years and it travels farther from the Sun, causing periods of global cooling. d. Earth’s global weather patterns change in response to the size of the polar ice caps, plunging Earth into a global

42. 22. After examining the 250-million-year fossil record, 2 paleontologists have uncovered evidence suggesting that the rate of species extinctions peaks every 26 million years. Supporters of the asteroid-impact theory would most likely favor which of the following explanations to account for this finding? a. Some massive object periodically disrupts the solar system, causing comets and asteroids to enter the inner solar system. b. The tilt of Earth’s axis changes every 26 million years, causing long-term climatic changes that lead to mass-extinction episodes. c. Earth’s orbit becomes more elliptical every 26 million years and it travels farther from the Sun, causing periods of global cooling. d. Earth’s global weather patterns change in response to the size of the polar ice caps, plunging Earth into a global

43. 12/4
1. What happens to the apparent wavelength of an object as it approaches?
2. What happens to the wavelength of an object as it goes away?

44. Electromagnetic radiation
What happens to the wavelength as the wave moves away
Electromagnetic radiation – a type of energy that travels at light speed through a vacuum
Give examples of each

46. 12/5 1. What does the balloon represent?
2. What do the dots represent?
3. What is the purpose of the lab?
4. How could you graph the data?
Final distance vs initial distance (x – axis independent)

47. 4. Students login to their CFS and click “Survey” > “Start” > “Select a Teacher”

48. Hubble’s law – the universe is expanding and will continue to expand, the further away a galaxy, the faster it moves away

50. Red shift – change in color frequency due to stars moving away
Redshift is a shift in absorption bands toward the red end of the spectrum. What could make the absorption bands of a star shift toward the red?

51. Expansion lab due today!!
12/8
Read the graph and describe what happen to the temperature of the universe as it expanded?
How do we know that the universe is expanding?
Expansion lab due today!!

53. 12/9 What are some types of fuels?
What does it mean when things fuse together?
What powers the stars? ?

54. 100 k =
Why research fusion?
Breakeven – where energy in = energy out

55. Fusion – the process which atoms fuse together, produces a large amount of energy that powers the stars
How do we know about fusion?

56. How do astronomers determine distances of stars and galaxies?
They follow the light
How do astronomers determine distances of stars and galaxies?
Flashlight, photon cannon

57. Cosmic background radiation
Big bang – how the universe started
Cosmic background radiation – energy that is found everywhere in the galaxy - 4 degrees
You might want to underline below
Dark matter – 75 percent of the universes mass does not give off electromagnetic radiation
Dark energy – mysterious force that is causing everything to accelerate

58. Why were the dark ages dark – gravity need time to pull everything toger

59. Any mass, not just a black hole, bends light
Any mass, not just a black hole, bends light. A spectacular example of gravitational lensing is the galaxy cluster

60. Parallax warm up
1. Stretch your arm out and stick up your thumb. How does your thumb move when you blink each eye? (create a diagram)
2. Bring your thumb in about half the distance and repeat.
What do you notice about the distance of your thumb and the change in position.
3. How can astronomers tell how far away stars are
Closer stars appear to move more.

61. Parallax – method used to tell distance from earth using apparent motion
Larger stars die faster

62. What are 3 things you can tell me about the diagram above?
12/10
What are 3 things you can tell me about the diagram above?
How do solar systems form?
Activity close reading - explain how redshift is used for evidence for the expanding universe
- key idea
Stars of the universe grand tour

63. How is it like looking back in time
Recent Hubble Space Telescope observations shed considerable light on the birth of stars and associated planetary systems. The following image shows regions in the Orion Nebula where solar systems may be forming
How is it like looking back in time
Baby stars

64. Solar system
Planetesimals – large astroids like pluto that helped form planets
Nebula –large clouds of dust

65. 1. What are three patterns you notice in this graph?
2. What color do hotter stars burn at?
3. What you think are the 4 families of stars?
Fun fact : Larger stars die faster!
1. Looking at the main sequence we see that

67. 1. What is the surface temperature of the sun?
12/11/2014
1. What is the surface temperature of the sun?
2. If the sun were hotter, what color would it be?
3. What is the relationship between brightness and surface temperature for main sequence stars?
Larger stars die faster!
6,000 degrees Kelvin
The sun would be blue if it were hotter.
As the temperature increases, the brightness also increases. This is a direct relationship as opposed to an inverse relationship
Agenda
- To read or to scan?
Tips for ACT
Practice test
Group study
Class discussion

68. 12/11
What are two main things you think should keep in mind when taking the science ACT?
Do you think it is better to read everything first or scan first? (lets carry out this experiment: I will describe experiment)

69. Student survey Class period Unsure (a) Better to scan text (b)
Better to read everything first
(Close reading)
3rd hour initial response 4 6
3rd hour final response 2 1 5
4th hour initial response 8 9
4th hour final response
Background :
Many students and tutors claim it is best to scan, read questions, scan text by students.
Certain text authors claim it is better to read everything carefully first.

70. Tips on taking ACT
Tips on science ACT : - Focus on what is supported by the text - Look for patterns in the graphs - Science is a process – don’t worry about what you don’t understand
Find text based evidence

71. Types of questions found in ACT 1. Data representations
2. Research summaries
3. Conflicting view points
Wonderings:
Are research summaries more likely in biology, chem or

72. Conclusions
What are some different tactics you use to study for the ACT?
When studying it is best to read carefully and mark the text; percent

73. Conclusions
What are some different tactics you use to study for the ACT?
When studying it is best to read carefully and mark the text

75. 1st hour initial response 1 9 4 1st hour final response
Results
Class period
unsure
Scan text
Close reading
1st hour initial response 1 9 4
1st hour final response
2nd hour initial response 3 2
2nd hour final response 12
3rd hour initial response 6
3rd hour final response 5
4th hour initial response 8
4th hour final response