THE PRIMORDIAL EARTH THE PRIMORDIAL EARTH Hadean and Archean Eons

Name: THE PRIMORDIAL EARTH THE PRIMORDIAL EARTH Hadean and Archean Eons
Uploaded: 2017-08-17T00:47:24+00:00
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Description: THE PRIMORDIAL EARTH THE PRIMORDIAL EARTH Hadean and Archean Eons

THE PRIMORDIAL EARTH THE PRIMORDIAL EARTH Hadean and Archean Eons
Formation of the Solar System The Solar Nebula Hypothesis

Formation of the Solar System The Solar Nebula Hypothesis Planets revolve around sun in same direction Counter-clockwise

Formation of the Solar System The Solar Nebula Hypothesis Planets lie roughly within sun's equatorial plane (plane of sun's rotation)

Formation of the Solar System The Solar Nebula Hypothesis Solar system is disk-like in shape

Formation of the Solar System The Solar Nebula Hypothesis 4. Planets rotate CCW on their axes, except for: Venus - slowly CW Uranus - on its side Pluto - on its side

Formation of the Solar System The Solar Nebula Hypothesis Moons go CCW around planets (with a few exceptions)

Formation of the Solar System The Solar Nebula Hypothesis Distribution of planet densities and compositions is related to their distance from sun

Inner, Terrestrial planets have high density

Outer, Jovian planets have low density

Formation of the Solar System The Solar Nebula Hypothesis 7. Age - Moon and meteorites 4.6 billion years

Formation of the Solar System The Solar Nebula Hypothesis Cold cloud of gas and dust, contracts, flattens, and rotates. Turbulence in cloud caused matter to collect in certain locations. Accretion of matter around central mass to form protoplanets (cold accretion).

Formation of the Solar System The Solar Nebula Hypothesis 90% of mass to center. Cloud condensed, shrank, and heated by gravitational compression to form Sun. Solar wind drove lighter elements outward causing observed distribution of masses and densities.

THE PRIMORDIAL EARTH Hadean and Archean Eons Meteorites
Meteorites are chunks of rock from the solar system that have impacted the Earth. They include fragments of the following objects that were broken off by collisions with other solar system objects: Asteroids Moon rock Planets, such as Mars (Martian meteorites)

Types of Meteorites Ordinary chondrites Most abundant type of meteorite About 4.6 billion years old, May contain chondrules (spherical bodies that solidified from molten droplets thrown into space during solar system impacts)

Types of Meteorites Carbonaceous chondrites a. Contain about 5% organic compounds, including amino acids (building-blocks of proteins, DNA, and RNA) b. May have supplied basic building blocks of life to Earth c. Contain chondrules

Types of Meteorites 3. Achondrites - stony meteorites without chondrules, resembling basalt

Types of Meteorites 4. Iron meteorites Iron-nickel alloy a. Coarse-grained intergrown crystal structure (Widmanstatten pattern) b. About 5% of all meteorites

Types of Meteorites 5. Stony-irons Composed partly of Fe, Ni and partly of silicate minerals, including olivine (like Earth's mantle). a. About 1% of all meteorites. Least abundant type.

Proterozoic Eon byBP Archean Eon byBP Hadean Eon byBP

THE PRIMORDIAL EARTH Hadean and Archean Eons
Accretion and Differentiation Origin of the Earth's Internal Layering Solar Nebular Theory or Cold Accretion Model (secondary differentiation): Earth was originally homogeneous.

Accretion and Differentiation Origin of the Earth's Internal Layering Earth formed by accretion of dust and larger particles of metals and silicates.

Accretion and Differentiation Origin of the Earth's Internal Layering Origin of layering requires a process of differentiation.

Accretion and Differentiation Origin of the Earth's Internal Layering Differentiation is the result of heating and at least partial melting.

Accretion and Differentiation Origin of the Earth's Internal Layering Iron and nickel sink to form core.

Accretion and Differentiation Origin of the Earth's Internal Layering Less dense material (silicon and oxygen mixed with remaining iron and other metals) forms mantle and lighter crust (primarily silicon and oxygen).

Accretion and Differentiation Origin of the Earth's Internal Layering Presence of volatile gases on Earth today indicates that complete melting did not occur.

Accretion and Differentiation Source(s) of heat for melting? 1. Accretionary heat from bombardment

Manicouagan Crater, Quebec myBP

Accretion and Differentiation Chicxulub (Mayan Tail of the Devil, Mexico) Cretaceous-Tertiary (K-T) Boundary

Barringer Crater, AZ 49,000 yBP

Tunguska, Siberia 30 June, 1908

THE PRIMORDIAL EARTH Hadean and Archean Eons Samuel Taylor Coleridge
The Rime of the Ancient Mariner: The upper air burst into life! And a hundred fire-flags sheen, To and fro they were hurried about! And to and fro, and in and out, The wan stars danced between And the coming wind did roar more loud, And the sails did sigh like sedge; And the rain poured down from one black cloud; The Moon was at its edge may have been inspired by the Leonid meteor shower that he witnessed in 1797

Accretion and Differentiation Source(s) of heat for melting? 2. Heat from gravitational compression

Accretion and Differentiation Source(s) of heat for melting? 3. Radioactive decay

Accretion and Differentiation 2. Hot Accretion Model - (primary differentiation): Originally hot, heterogeneous Earth Zoning developed during cooling High-temperature crystallization elements (Fe, Ni) cool first and form Earth's core Low-temperature crystallization (Si, O) elements cool late to form Earth's crust

THE PRIMORDIAL EARTH Hadean and Archean Eons The Hadean Crust
Dominated by iron and magnesium silicates. If Earth experienced heating and partial melting, it may have been covered by an extensive magma ocean in the Hadean. Magma cooled to form rocks called komatiites. Komatiites form at temperatures greater than those at which basalt forms (greater than 1100oC). Komatiites are ultramafic rocks composed mainly of olivine and pyroxene. Formed Earth's Hadean crust.

THE PRIMORDIAL EARTH Hadean and Archean Eons The Hadean Crust

THE PRIMORDIAL EARTH Hadean and Archean Eons Early Continental Crust

THE PRIMORDIAL EARTH Hadean and Archean Eons Modern Crust

Evolution of the Atmosphere First Atmosphere Earth's atmosphere has evolved or changed over time. Earth's first, primitive atmosphere lacked free oxygen. The primitive atmosphere was derived from gases associated with the comets and meteorites which formed the Earth formed during accretion.

Evolution of the Atmosphere First Atmosphere Composition - Probably H2, He These gases are relatively rare on Earth compared to other places in the universe and were probably lost to space early in Earth's history because Earth's gravity is not strong enough to hold lighter gases

Evolution of the Atmosphere First Atmosphere Earth still did not have a differentiated core (solid inner/liquid outer core) which creates Earth's magnetic field (magnetosphere = Van Allen Belt) which deflects solar winds. Once the core differentiated the heavier gases could be retained

Evolution of the Atmosphere Second Atmosphere Produced by volcanic out gassing. Gases produced were probably similar to those created by modern volcanoes H2O, CO2, SO2, CO, S2, Cl2, N2, H2, and NH3 (ammonia) and CH4 (methane) No free O2 at this time (not found in volcanic gases).

THE PRIMORDIAL EARTH THE PRIMORDIAL EARTH Hadean and Archean Eons

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