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A100 Oct. 6 The Earth

A100 Oct. 6 The Earth. READ Chapter 5 – The Earth Homework 4 Due Friday Quiz on Friday. Today’s APOD. The Sun Today.

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A100 Oct. 6 The Earth

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  1. A100 Oct. 6 The Earth • READ Chapter 5 – The Earth • Homework 4 Due Friday • Quiz on Friday Today’sAPOD The Sun Today

  2. Looking outward to the blackness of space, sprinkled with the glory of a universe of lights, I saw majesty – but no welcome. Below was a welcoming planet. There, contained in the thin, moving, incredibly fragile shell of the biosphere is everything that is dear to you, all the human drama and comedy. That’s where life is; that’s where all the good stuff is. Loren Acton (1936 – ) U.S. astronaut

  3. The Earth from Space • Understanding Earth helps us understand other planets • Understanding other planets helps us understand the Earth • How has Earth has changed over time • Why does it change? • How does it differ from other planets?

  4. Size and Shape of the Earth • The Earth is a huge, rocky sphere spinning in space and moving around the Sun at a speed of about 100 miles every few seconds • Earth also has a blanket of air and a magnetic field that protects the surface from the hazards of interplanetary space

  5. Distance from Sun 1 AU = 1.5 x 108 km Orbital velocity 30 km / second Orbital period 365.256 days Rotation period 23.9345 hours Inclination of equator to orbit: 23.26 degrees Diameter: 12,756 km Mass 6 x 1024 kg Mean density 5.5 gm/cm3 Surface temperature -130 F to +140 F (avg. 70F) Earth Data

  6. An Average Planet • Our Earth is about average • Earth is the largest and most massive of the four terrestrial planets, but smaller and less massive than the four giant, or Jovian, planets. • Earth is third in distance from the Sun among the four terrestrial planets. • Earth has a moderately dense atmosphere; 90 times less dense than that of Venus but 100 times denser than that of Mars.

  7. Unique Features of Earth • Plate Tectonics – theonly planet with a surface shaped by this type of tectonics • Atmospheric Oxygen – the only planet with significant Oxygen in its atmosphere • Surface Liquid Water – theonly planet where temperature & pressure allow surface water to be stable as a liquid • Climate Stability - differs from Venus & Mars in having a relatively stable climate • Life – Theonly world known to have life; it certainly has abundant & diverse life forms • Magnetic Field • Large moon

  8. Size and Shape of the Earth • The Earth is large enough for gravity to have shaped it into a sphere • More precisely, Earth’s spin makes its equator bulge into a shape referred to as an oblate spheroid – a result of inertia

  9. Composition of the Earth • The most common elements of the Earth’s surface rocks are: • oxygen (45.5% by mass), • silicon (27.2%), • aluminum (8.3%), • iron (6.2%), • calcium (4.66%), and • magnesium (2.76%) • Silicon and oxygen usually occur together assilicates • Ordinary sand is the silicate mineral quartz and is nearly pure silicon dioxide

  10. Density of the Earth • Density is a measure of how much material (mass) is packed into a given volume • Typical unit of density is grams per cubic centimeter • Water has a density of 1 g/cm3, ordinary surface rocks are 3 g/cm3, while iron is 8 g/cm3 • For a spherical object of mass M and radius R, its average density is given by • For Earth, this density is found to be 5.5 g/cm3 • Consequently, the Earth’s interior (core) probably is iron (which is abundant in nature and high in density)

  11. What’s Inside? • Crust • Asthenosphere • Mantle • Outer Core • Inner Core

  12. How do we know this? • Earthquakes generateseismic waves that move through the Earth with speeds depending on the properties of the material through which they travel • These speeds are determined by timing the arrival of the waves at remote points on the Earth’s surface • A seismic “picture” is then generated of the Earth’s interior along the path of the wave A sonogram of the Earth

  13. A solid, low-density and thincrustmade mainly of silicates A hot, thick, not-quite-liquid mantlewith silicates A liquid, outer corewith a mixture of iron, nickel and perhaps sulfur A solid, inner coreof iron and nickel Interior Structure of the Earth

  14. Differentiation occurs in a mixture of heavy and light materials if these materials are liquid for a long enough time The Earth must have been almost entirely liquid in the past The densest materials are at the center of the Earth and the least dense materials are at the surface – differentiation Differentiation

  15. 0 Earth’s Interior Earth’s interior gets hotter towards the center (6500K, as hot as the Sun’s surface) • The Earth’s inner nickel/iron core is solid because the high pressure (from overlying materials) forces it into a solid state – even at that high temperature • The outer core is liquid nickel/iron

  16. Why so hot??? The high temperature in the Earth’s core (6500K) is probably due to two causes • Left-over heat from the impact of small bodies that eventually formed the Earth • The radioactive decay of radioactive elements that occur naturally in the mix of materials that made up the Earth

  17. The Earth cools very slowly • Heat is trapped inside the Earth’s interior due to the long time it takes to move to the surface and escape Pseudo-color infrared image of the Earth from space. The red areas are warm water during an El Nino event

  18. Age of the Earth • Radioactive decay used to determine the Earth’s age • Radioactive atoms decay intodaughter atoms • The more daughter atoms there are relative to the original radioactive atoms, the older the rock is

  19. Age of the Earth • Radioactive potassium has a half-life of 1.28 billion years and decays into argon, which is a gas that is trapped in the rock unless it melts • Assume rock has no argon when originally formed • Measuring the ratio of argon atoms to potassium atoms gives the age of the rock • This method gives a minimum age of the Earth as 4 billion years • Other considerations put the age at 4.5 billion years

  20. 0 Early History of Earth • Four main stages of evolution: • Differentiation • Bombardment • Cooling • Surface evolution Earth formed 4.6 billion years ago from the inner solar nebula Most traces of ancient bombardment (impact craters) have been destroyed by later geological activity

  21. 0 Meteorite Impacts Still Occur Famous example: Barringer Crater near Flagstaff, AZ: 1.2 km diameter 200 m deep Over 150 impact craters found on Earth. Formed ~ 50,000 years ago by a meteorite of ~ 80 – 100 m diameter

  22. 0 The Chicxulub Crater Comet nucleus impact producing the Chicxulub crater ~ 65 million years ago may have caused major climate change, leading to the extinction of many species, including dinosaurs. The impact of a large body formed a crater ~ 180 – 300 km in diameter in the Yucatán peninsula, ~ 65 million years ago Evidence of the event is seen in rock layers around the world

  23. ASSIGNMENTSthis week Dates to Remember • READ Chapter 5 – The Earth • Homework 4 Due Friday • Quiz on Friday

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