Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mercury = 5.4 g/cm 3 (Earth 5.5 g/cm 3 ) = 0.38 that of Earth Mass Radius Density Gravity = 3.3 x 10 26 g = 0.055 M Earth  = 2439 km = 0.38 R Earth Semimajor.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Mercury = 5.4 g/cm 3 (Earth 5.5 g/cm 3 ) = 0.38 that of Earth Mass Radius Density Gravity = 3.3 x 10 26 g = 0.055 M Earth  = 2439 km = 0.38 R Earth Semimajor."— Presentation transcript:

1 Mercury = 5.4 g/cm 3 (Earth 5.5 g/cm 3 ) = 0.38 that of Earth Mass Radius Density Gravity = 3.3 x 10 26 g = 0.055 M Earth  = 2439 km = 0.38 R Earth Semimajor axis = 0.39 AU

2 Venus Mass = 0.82 M Earth Radius = 0.95 R Earth  Density = 5.2 g/cm 3 Average distance from Sun = 0.72 AU Orbital period = 225 days Rotation period = 243 days (longer than orbital period, and retrograde!)

3 General Features Mass: M Earth = 6 x 10 27 g Radius: R Earth = 6378 km Density:  = 5.5 g/cm 3 Age: 4.6 billion years Orbital period = 365 days Rotation period = 1 day

4 Mars Mass = 0.11 M Earth Radius = 0.53 R Earth Density = 3.9 g/cm 3 Average distance from Sun = 1.52 AU eccentricity = 0.093 Range in distance from Sun = 1.38 - 1.66 AU Rotation Period = 24.6 hours Orbital Period = 687 days

5 Terrestrial Planets' Spin, Habitability

6 Clicker Question: Venus and the Earth are very similar (within 10%) in their: A: Amount of carbon dioxide in their atmospheres. B: Distance from the Sun. C: Surface gravity. D: Length of a day. E: All of the above.

7 Clicker Question: Large scale motions of the crust (plate tectonics) are seen on which planets: A: Mercury and Venus B: Earth, Venus and Mars C: Only the Earth D: Mars and Venus E: All terrestrial planets - Mercury, Venus, Earth and Mars.

8 Clicker Question: It takes 8 minutes for light to travel 1 AU, how long does it take for a radar signal to travel from Earth to Mercury and back at its closest point to Earth in its orbit? A: 1 minute B: 10 minutes C: 2 hours D: 2 days E: 1 year

9 The Martian Atmosphere - 95% CO 2 - Surface Pressure 0.006 that of Earth's atmosphere (thin air!) - Surface Temperature 250 K. - Dust storms sometimes envelop most of Mars, can last months. A "Reverse Runaway Greenhouse Effect" may have happened: during volcanic phase (first two billion years), thicker atmosphere, warmer surface, possibly oceans. But gradually most CO 2 dissolved into surface water and combined with rocks, then atmospheric and surface water froze (creating ice caps and possible permafrost layer). Or: most atmosphere lost due to low gravity Or: most atmosphere lost due to heating by early impacts

10 Demo - The Atmosphere of Mars or Fun with Carbon Dioxide

11 The Martian Surface Valles Marineris Olympus Mons Tharsis Bulge Hellas Basin Southern Hemisphere ~5 km higher elevation than Northern, and more heavily cratered. South is like lunar highlands, surface ~4 billion years old, North like maria, ~3 billion years old. Valles Marineris - 4000 km long, up to 7 km deep. Ancient crack in crust. Reasons not clear. Tharsis Bulge - highest (10 km) and youngest (2-3 billion years) region. Olympus Mons - shield volcano, highest in Solar System, 3x Everest in height. 100 km across. Hellas Basin - large impact crater, ~4 billion years old. (Mars Global Surveyor radar data)

12 The View From the Surface Viking 1 site (1976) Sojourner robot from Pathfinder (1997) “Endurance” crater from Opportunity rover (2004) Dry, desert-like. Red => high iron content. Mars didn't differentiate as completely as Earth. Sky has butterscotch hue due to dust.

13 Red arrows: rounded boulders indicating water erosion? White arrows: "conglomerate" rock, like in Earth's riverbeds? Blue arrows: sharp-edged boulders, volcanic rock? Pathfinder site was an outflow channel

14 Spirit and Opportunity Rovers Scenes from “Roving Mars” (start at 20:27)

15 Opportunity’s first pictures from Victoria Crater Deepest crater explored by far (230 feet, 10 times deeper than Endurance Crater) => more layers of geologic history. Will it go in? Will it ever get out?

16 Mars Reconnaissance Orbiter view of Victoria Crater

17 Opportunity panorama: inside Victoria Crater Deepest crater explored by far (230 feet) => apparently it was the top of an underground water table.

18 Evidence for Past Surface Water "runoff channels" or dry rivers "outflow channels" teardrop "islands" in outflow channels standing water erosion in craters?

19 Did Mars once have a huge ocean? Long stretches along border are very even in elevation, like a coastline Ocean fed by outflow channels from higher elevation southern hemisphere?

20 Clicker Question: The largest mountain in our solar system is: A: Caloris Basin range on Mercury B: Gula Mons on Venus C: Mt. Everest on Earth D: Olympus Mons on Mars.

21 Clicker Question: Where is the water that once flowed on the surface of Mars? A: In the atmosphere B: In the polar caps only C: In a layer of permafrost below the surface and in the polar caps D: It was diverted to Los Angeles

22 Evidence for "Permafrost" layer beneath surface "Splosh" craters suggesting liquefied ejecta.

23 Phoenix mission – icy soil at the poles! Phoenix analyzing scooped up dirt – was Mars ever favorable for microbial life? Organic compounds?

24 Valles Marinaris flyover movie

25 Mars' History Smaller than Earth, Mars cooled faster. Most volcanic activity ended two billion years ago. Differentiation less complete than on Earth. No evidence for plate tectonics. Atmosphere mostly froze out into subsurface ice, polar ice caps and surface rocks.

26 Next mission – Mars Science Laboratory – 2011 launch

27 Mars' Moons Phobos and Deimos Phobos: 28 x 20 km Deimos: 16 x 10 km Properties similar to asteroids. They are probably asteroids captured into orbit by Mars' gravity.

Download ppt "Mercury = 5.4 g/cm 3 (Earth 5.5 g/cm 3 ) = 0.38 that of Earth Mass Radius Density Gravity = 3.3 x 10 26 g = 0.055 M Earth  = 2439 km = 0.38 R Earth Semimajor."

Similar presentations

Chapter 7 Earth and the Terrestrial Worlds

Chapter 7 Earth and the Terrestrial Worlds
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
ASTR100 (Spring 2008) Introduction to Astronomy Earth as a Planet Prof. D.C. Richardson Sections 0101-0106.

ASTR100 (Spring 2008) Introduction to Astronomy Earth as a Planet Prof. D.C. Richardson Sections
Lecture Outlines Astronomy Today 8th Edition Chaisson/McMillan © 2014 Pearson Education, Inc. Chapter 10.

Lecture Outlines Astronomy Today 8th Edition Chaisson/McMillan © 2014 Pearson Education, Inc. Chapter 10.
Mars Astronomy 311 Professor Lee Carkner Lecture 14.

Mars Astronomy 311 Professor Lee Carkner Lecture 14.
Mars Astronomy 311 Professor Lee Carkner Lecture 14.

Mars Astronomy 311 Professor Lee Carkner Lecture 14.
April 11, 2006Astronomy 20101 Chapter 9 Earth-Like Planets: Venus and Mars Venus and Mars resemble Earth more than any other planets. Is it possible that.

April 11, 2006Astronomy Chapter 9 Earth-Like Planets: Venus and Mars Venus and Mars resemble Earth more than any other planets. Is it possible that.
Interiors of Terrestrial Planets. Mercury MEAN RADIUS: 2439.7 km MASS: 0.055 (Earth=1) DENSITY: 5.43 (g/cm^3) GRAVITY: 0.376 (Earth=1) ORBIT PERIOD: 87.97.

Interiors of Terrestrial Planets. Mercury MEAN RADIUS: km MASS: (Earth=1) DENSITY: 5.43 (g/cm^3) GRAVITY: (Earth=1) ORBIT PERIOD:
Mars. Some similarities between Mars & Earth Mars’ Bulk Properties Mars has days & seasons like Earth.

Mars. Some similarities between Mars & Earth Mars’ Bulk Properties Mars has days & seasons like Earth.
Mysteries of Earth and Mars Mars Facts and Exploration.

Mysteries of Earth and Mars Mars Facts and Exploration.
Astronomy Picture of the Day. Mercury Mass = 0.055 M Earth Radius = 0.38 R Earth  Surface Temp: 100 - 700 K Average distance from Sun =.39 AU Moonlike:

Astronomy Picture of the Day. Mercury Mass = M Earth Radius = 0.38 R Earth  Surface Temp: K Average distance from Sun =.39 AU Moonlike:
Astronomy Picture of the Day. Mercury Mass = 0.055 M Earth Radius = 0.38 R Earth  Surface Temp: 100 - 700 K Moonlike: Surface craters, no atmosphere.

Astronomy Picture of the Day. Mercury Mass = M Earth Radius = 0.38 R Earth  Surface Temp: K Moonlike: Surface craters, no atmosphere.
Red Planet Mars Chapter Thirteen. Guiding Questions 1.When is it possible to see Mars in the night sky? 2.Why was it once thought that there are canals.

Red Planet Mars Chapter Thirteen. Guiding Questions 1.When is it possible to see Mars in the night sky? 2.Why was it once thought that there are canals.
The Terrestrial Planets, Part III Mars. MARS The God of War.

The Terrestrial Planets, Part III Mars. MARS The God of War.
The Solar System.

The Solar System.
Chapter 6 The Terrestrial Planets. Units of Chapter 6 Orbital and Physical Properties Rotation Rates Atmospheres The Surface of Mercury The Surface of.

Chapter 6 The Terrestrial Planets. Units of Chapter 6 Orbital and Physical Properties Rotation Rates Atmospheres The Surface of Mercury The Surface of.
© 2011 Pearson Education, Inc. Venus and Mars. © 2011 Pearson Education, Inc. Venus.

© 2011 Pearson Education, Inc. Venus and Mars. © 2011 Pearson Education, Inc. Venus.
Chapter 7 Earth and The Terrestrial Worlds Principles of Comparative Planetology Comparative Planetology is the study of the solar system through examining.

Chapter 7 Earth and The Terrestrial Worlds Principles of Comparative Planetology Comparative Planetology is the study of the solar system through examining.
Unit 2 Lesson 4 The Terrestrial Planets Copyright © Houghton Mifflin Harcourt Publishing Company.

Unit 2 Lesson 4 The Terrestrial Planets Copyright © Houghton Mifflin Harcourt Publishing Company.
Mars Mars is a dry dead world. There are no Martian transits.

Mars Mars is a dry dead world. There are no Martian transits.

Similar presentations

Ads by Google