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Module 2 - Planetary Formation and Differentiation

1. Introduction - The origin of the Solar System

The fundamental matter making up you and everything around you are thought to first have originated 13.7 billion years ago during the big bang, a gigantic explosion thought to be the origin of our present universe. The universe expanded rapidly from a very dense and incredibly hot state and continues to expand to this day.

The tiny particles that made up the fundamental matter began to come together to form larger clumps due to electrostatic forces between particles. As these clumps grew larger and larger their mass was sufficient to cause strong enough gravitational forces to bring the clumps together to form larger clumps. As the clumps became larger and more dense they began to generate heat and light by a nuclear process called nuclear fusion, which eventually because very large bright features that are the stars.

Nuclear fusion is a nuclear reaction in which two or more atomic nuclei become very close and collide at very high speed to form a new nucleus. The Sun is primarily fueled by the nuclear fusion reaction that involves two hydrogen atoms to form one helium atom releases photons (light and heat energy). Other stars with greater masses (~1.5 times the mass of the Sun) may generate carbon, nitrogen, or oxygen.

Insert table of important stellar element.

After a star forms, it is considered a main sequence star. Our Sun is considered a main sequence star, which is defined by where it plots on a graph of the star’s brightness (luminosity) against its temperature (a function of color), known as the Hertszprung-Russell diagram (H-R diagram).

The more massive a star is, the shorter its lifespan on the main sequence. Given enough time, a star’s hydrogen fuel will be consumed, and it will evolve away from the main sequence in the H-R diagram. How a star evolves depends on its mass; stars ~35% of the mass of the Sun evolve into white dwarfs directly, whereas stars with up to 10 times the mass of the sun pass through a red giant stage. More massive stars can explode as a supernova, or collapse directly into a black hole.

By normal nuclear fusion reactions, stars can only produce elements up to a certain atomic mass (iron with 56 atomic mass units). Because heavier elements (like nickel, zinc, and gold) are found in our Solar System, these elements must have formed some other way. Runaway nuclear fusion during supernova explosion is thought to be responsible for the formation of heavier elements.

And in fact, our Solar System is thought to have formed ~4.55 billion years ago after the dramatic and catastrophic destruction of a massive star by a supernova explosion.

From a human perspective, supernovae are relatively rare occurrences (only three Milky Way supernovae in in the last 1000 years). One historical supernova was described by Chinese astronomers in 1054 A.D. and the remnants of this event make up the Crab Nebula (located in the constellation Taurus).

In this module, you will learn about:

The Solar Nebula
Ordinary, but also Extra-Ordinary: Chondrite Meteorites
Processes in the protoplanetary disk
Impacts!
Planetary differentiation
- Density
Layers of differentiated bodies
- Core
- Mantle
- Crust
- Atmosphere
Giant impact hypothesis
Summary and concluding remarks

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The Big Bang This dominant cosmological theory suggests the Universe began nearly 13.7 billion years ago, expanding rapidly from a very dense and incredibly hot state. Eventually, stars ignited and galaxies slowly formed. The Big Bang theory has been imporved and advanced especially through NASA's Cosmic Background Explorer (COBE) and WMAP missions. This animation conceptualizes these explosive beginnings of the Universe. Note: This animation begins with a pinpoint of light as the Big Bang, and continues to show the formation of the first stars and galaxies. Animator: Dana Berry (Skyworks Digital). Writer: Michael D. McClare (HTSI).
H-R Diagram An HR diagram showing many well known stars in the Milky Way galaxy. In the Hertzsprung-Russell diagram the temperatures of stars are plotted against their luminosities. The position of a star in the diagram provides information about its present stage and its mass. Stars that burn hydrogen into helium lie on the diagonal branch, the so-called main sequence. Red dwarfs like AB Doradus C lie in the cool and faint corner. AB Dor C has itself a temperature of about 3,000 degrees and a luminosity which is 0.2% that of the Sun. When a star exhausts all the hydrogen, it leaves the main sequence and becomes a red giant or a supergiant, depending on its mass (AB Doradus C will never leave the main sequence since it burns so little hydrogen). Stars with the mass of the Sun which have burnt all their fuel evolve finally into a white dwarf (left low corner).
Crab Nebula Animations Animation and Composite Image of Crab Nebula. MPEG This sequence begins with an artist's animation of the explosion that produced the Crab Nebula, now an expanding debris field of extremely high-energy particles created from the death of a massive star. The view then fades into an image of the Crab composed of data from Chandra (light blue), Hubble (green and dark blue), and Spitzer (red). [Runtime: 0:18]