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Chapter 27: Planets of the solar system

Chapter 27: Planets of the solar system. Section 27.1 – Formation of the Solar System. What exactly is a solar system anyway? Consists of the Sun, all the planets, and any other body that revolves around the Sun And what exactly is a planet?

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Chapter 27: Planets of the solar system

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  1. Chapter 27: Planets of the solar system

  2. Section 27.1 – Formation of the Solar System • What exactly is a solar system anyway? • Consists of the Sun, all the planets, and any other body that revolves around the Sun • And what exactly is a planet? • Any primary bodies that orbit the Sun (Earth, Venus, etc.) • Where did it all come from?

  3. Nebular Hypothesis • 1976, French mathematician Pierre-Simon, marquis de Laplace came up with explanation for creation of the solar system • Sun and other planets came together and condensed at the same time out of a rotating cloud of gas and dust

  4. Solar Nebula • Solar Nebula – the rotating cloud of gas and dust from which the sun and planets formed • Also any nebula from which stars and planets (outside our solar system) may form • 99% of the material in the Sun is matter that was originally in the solar nebula

  5. Steps in the process 1.) Start with a solar nebula (rotating cloud of gas and dust) 2.) Contraction of gas and dust into rotating disk 3.) Cooling causing condensing into tiny (dust sized) solid particles 4.) Collisions between these form larger bodies 5.) The larger bodies accrete (or build up) to form planets

  6. Let’s break it down into steps… #1 Solar Nebula What “fuels” the nebula? Energy from collisions and pressure from gravity makes the center of the nebula HOT and DENSE 99% of all the material in the nebula is in the sun Think back to our solar nebula activity! Where is most of the material located?

  7. Next Step… #2 The nebula flattens as it rotates and gets warmer near the center Starts to look like a disk Temperature begins to rise more at the center Think ice skater doing a spin!!

  8. Third Step… #3 Things begin to form Planetsimals begin to form within the swirling disk As they grow, gravitational pull increases and they continue to grow more Planetesimals - “mini planets” or small bodies from which a planet originated in the early stages at the beginning of the solar system)

  9. Fourth Step… #4 Small planetesimals collide with larger ones and the planets begin to grow As the planetesimals get bigger, their gravity grows and they become protoplanets Protoplanets are planetesimals that have collided due to gravity to form larger bodies

  10. Fifth Step… #5 The extra dust and gas is gradually removed from the solar nebula by the collisions The removal of the other material leaves mainly just planets around the sun and creates a new solar system

  11. Creation of Planets KEY THOUGHT: THE FEATURES OF A NEWLY FORMED PLANET DEPEND ON THE DISTANCE BETWEEN THE PROTOPLANET AND THE DEVELOPING SUN IT ALL RELATES TO GRAVITY What has the most gravity in a solar system? THE SUN!

  12. Inner vs. Outer Planets • Inner protoplanets (which are?) contained lots of heavy elements • Venus, Earth and Mercury contain lots of nickel and iron • These elements stuck around because they couldn’t be blown away or evaporated by the Sun’s heat and wind

  13. More about inner planets • As the inner planets formed, dense material sank towards the middle of the planets and lighter material stayed on top, forming layers • Inner planets have solid surfaces (like Earth) • Inner planets are smaller, rockier, and denser than outer planets

  14. Inner vs. Outer Planets • Outer protoplanets (which are?) contained lighter elements • Jupiter, Saturn, Uranus, and Neptune contain hydrogen, helium, and methane • These planets are cold, have low densities, and are HUGE

  15. More on outer planets • Outer planets known as “Gas Giants” because: • Mostly made of gases and are low density • Jupiter’s density is only 24% of Earth’s but Jupiter’s diameter is 11 times Earth’s • Have liquid cores and gas outer layers

  16. Pluto! • Not considered an inner or outer planet • Characteristics of Pluto • Very small (smaller than Earth’s Moon!) • Very COLD – it’s an ice ball made of frozen rock and gas

  17. More on Pluto • Recently, scientists found many, many objects in the universe that are similar to Pluto beyond Neptune • Because Pluto is more like these other common objects rather than other planets, it is no longer considered a PLANET.

  18. Formation of Solid Earth • 3 sources of energy contributed to the original HOT temperatures on Earth: • Energy produced during collisions with other planetesimals • Increased pressure on inner layers of Earth from weight of outer layers • Radioactive materials were abundant in Earth during its formation

  19. Early Solid Earth • Differentiation – the process that occurred as Earth developed where denser molten materials sank to the center and less dense materials were forced to the outer layers

  20. 3 Layers of Earth • Core – the center of Earth that is made of dense rocks • Nickel and Iron most common • Mantle – Earth’s thick middle layer • Iron and Magnesium-rich rock • Crust – Outermost layer of Earth • Least dense material, including silica-rich rocks

  21. Present Solid Earth • As time went on, Earth’s surface cooled enough for solid rock to form • While Earth already had distinct layers, the surface continued to change from: • Heat inside the Earth • Impacts and interactions with the forming atmosphere

  22. Formation of Earth’s Atmosphere • Like the Earth’s interior, the atmosphere formed due to differentiation • Hydrogen and helium (lightest gases) rose to surface of the Earth • SO, the early atmosphere was mostly made of H and He

  23. The Early Atmosphere • Hydrogen and helium gas are so light, Earth’s gravity couldn’t hold them in for long • The Sun’s heat heated them up and they blew away into space • Also, Earth’s magnetosphere (protects our current atmosphere) was possibly not developed fully

  24. OUTGASSING (no that’s not what you think it is) • The Earth’s surface continued to evolve with creation of volcanoes and other land forms • Volcanoes released additional gases into atmosphere: • Water vapor, carbon dioxide, nitrogen, methane, sulfur dioxide, and ammonia • What’s missing from this list?????

  25. More on outgassing • Gases released from volcanoes then interacted with sun light and heat • Breakdown of ammonia and water vapor into OZONE (or three oxygen) • Ozone is a shield against UV rays of the Sun

  26. The PRESENT Atmosphere • Later, some plant life evolved that used carbon dioxide from the atmosphere to produce food (photosynthesis!) • OXYGEN is the main product of photosynthesis • About 2 billion years ago, the amount of oxygen in the atmosphere increased a lot • Composition of “air” is now stable

  27. Oceans – Where did they come from? • Possibly from space! • Some icy bodies (ex. comets) collided with Earth and added water vapor to atmosphere • As Earth cooled, water vapor condensed to liquid rain • First ocean was probably FRESH water

  28. Why are oceans salty? • Although first oceans were likely fresh, as water flowed over land and rocks, it dissolved minerals and salts carried them to the oceans • After the water cycle was in place, the concentration of salt in oceans increased

  29. How did Oceans Affect Atmosphere? • Scientists believe the early atmosphere was changed as oceans began to dissolve carbon dioxide • Current atmosphere likely has more carbon dioxide than original atmosphere • Earth’s early climate likely cooler than today • Does CO2 in the atmosphere affect climate today????

  30. ASSIGNMENTS • Outline Section 27.1 and Key Terms 27.1 • Due:

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