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Planet Building Part 1 Solar Nebula’s Chemical Composition 1 Chemical Composition • Everything astronomers know about the solar system indicates that it began as an interstellar gas cloud. – Cloud would have been mostly hydrogen with some helium – small amounts of the heavier elements. – One piece of evidence is that we see the composition of the gas cloud of the composition of the sun. 2 Chemical Composition • The suns elemental composition revealed by spectrum analysis indicates it is mostly hydrogen, helium (about 25%), and 2% other heavier elements. – Some hydrogen has been converted to helium due to fusion reactions. – Astronomers draw the conclusion, looking at other stars as well as the sun, that the solar nebula must have had the same composition. 3 Chemical Composition • We see evidence reflected in the planets – as we have discussed. – Inner planets are rock and metal while outer planets are rich in low-density gases such as hydrogen and helium. – The chemical composition of Jupiter resembles that of the sun. 4 Chemical Composition • If the low-density gases were allowed to escape from a body such as the sun or Jupiter, the remaining heavier elements would resemble Earth’s chemical composition. 5 Conversion of Matter • Important evidence for SNT comes from how nebular gas converted into solid matter. From Orion Nebula, what appears to be disks of dust and gas surrounding newly formed stars. From: http://atropos.as.arizona.edu/aiz/teaching/nats102/mario/solar_system.html 6 Conversion of Matter • The density-variations originated when the Solar System (SS) first formed solid grains. – The kind of matter that could condense in a particular region depended on temperature and the gas that was present. – In the inner regions the temperature was around 2,240 degrees Fahrenheit. – Only compounds with high melting points could condense (e.g. metal oxides and pure metals). 7 Conversion of Matter • A little farther out in the nebula – it was cooler allowing silicates (rocky material) to condense (along with metal). – Mercury, Venus, Earth, and Mars are composed of a mix of metals, metal oxides, and silicates. – Mercury is composed of more metals (closer to sun) with less metal as you proceed outbound from the sun. 8 Ice/Frost Line • Beyond Mars, there is the ice line, a boundary beyond which water vapor freezes to form ice particles. • Farther still from the sun, compounds like methane and ammonia condense to form other types of ice. • Water vapor, ammonia, and methane were abundant in the nebula. 9 Ice/Frost Line 10 Ice/Frost Line • Due to the abundance of water, methane, and ammonia, the nebula would have been a “blizzard” of ice particles. – Small amounts of silicates and metal (far, far less than in the inner SS) would also have been found there (having condensed). – We know this because, among other evidence, the Jovian planets are a mix of ices and small amounts of silicates and metal. 11 Condensation Sequence • Is the sequence in which different materials condense from the gas as you move away from the sun – toward lower temperatures. – The condensation sequence implies that different kinds of materials will condense in predictable ways – which is exactly what we see. 12 Condensation Sequence 13 Common Misconceptions • It is a common misconception that the solar nebula was sorted by density. – Heavier metals and rock “sinking” toward the sun and low-density gases blown outward. – This is not the case, the chemical composition of the solar nebula was originally roughly the same throughout the disk. – The important factor was temperature. The inner nebula was hot and the outer cold. 14 Common Misconceptions – Only rocks and metals could condense in the inner nebula. – The outer nebula, beyond the ice line, formed lots of ices along with metals and rock. – Ice line is the boundary between high-density planets and low-density planets. 15