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Harry Williams, Historical Geology 1 Follow up from last lecture: 1.Metamorphic rocks in California: https://en.wikipedia.org/wiki/Franciscan_Assemblage

HISTORICAL GEOLOGY PRECAMBRIAN GEOLOGY

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HISTORICAL GEOLOGY PRECAMBRIAN GEOLOGY. . Introduction Precambrian time = 87% of Earth history and yet much less is known about Precambrian history than Phanerozoic history (13%), because there are few fossils and the rocks are highly deformed. - PowerPoint PPT Presentation

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Page 1: HISTORICAL GEOLOGY PRECAMBRIAN GEOLOGY

Harry Williams, Historical Geology 1

Follow up from last lecture:1.Metamorphic rocks in California: https://en.wikipedia.org/wiki/Franciscan_Assemblage

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2. Oil in California:

California #4 in U.S. oil production in 2014.

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HISTORICAL GEOLOGYPRECAMBRIAN GEOLOGY.

IntroductionPrecambrian time = 87% of Earth history and yet much less is known about Precambrian history than Phanerozoic history (13%), because there are few fossils and the rocks are highly deformed.

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Formation of the Solar System and Earth – Solar Nebula Hypothesis

Clues: 1. All planets orbit the same direction and in the same plane around the sun.

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2. The inner planets are dense and rocky; the outer planets are less dense and gaseous.

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The Solar Nebula Hypothesis: whole solar system formed from a cloud of rotating dust and gas (explains why all planets rotate the same way).

As the cloud contracted under gravity, it flattened into a disk (explains the orbital plane).

Most material collected at the center (proto-sun), the rest collected in masses orbiting the sun (proto-planets).

Compression by gravity caused heating in the proto-sun until nuclear fusion started (hydrogen combined into helium). The resulting Solar Wind (charged atomic particles) drove lighter gases from the inner planets, leaving them rocky and denser (explains contrast in composition between inner and outer planets).

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When did all this occur? Based on dating the moon, meteorites and earth rocks, the earth formed about 4.6 billion years ago.Are any other planets like the earth? No – only earth seems to have liquid water (and lots of it). Mars probably used to have liquid water (seas) a long time ago (about 3.5 billion), but it has been stripped away by the solar wind.

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THE ARCHEAN (4.6-2.5 BILLION)The earth is about 4.6 billion years old. Either during or soon after its formation it was very hot and differentiated into a core and mantle. This was during the Archean Eon, which lasted about 2.1 billion years.

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The crust had not formed at this time – the surface was probably molten ultramafic rock, an extension of the mantle.

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As the surface cooled (over millions of years) the atmosphere was produced by outgassing and was probably similar to volcanic gases, modified by chemical processes e.g. H2O rained out -> oceans; H2 lost to space; CO reacted with H2O to form CO2 and H2; CO2 combined with Ca and Mg to form carbonate rocks (late in this period). The atmosphere was rich in carbon dioxide and water vapor, but had little to no oxygen.

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The mantle is made of ultramafic rock – dense rock made of ferromagnesium minerals such as olivine and pyroxenes (Silicate of Mg and Fe; and Silicates of Al, Ca, Mg and Fe). An intrusive example is peridotite; the extrusive form is komatiite – these solidify at higher temperatures than basalt. It is likely that patches of komatiite crust formed during the Archean, but being denser, sunk and were “recycled”.

komatiite

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The Archean CrustImportant question –

“how did the modern crust originate? (basalt oceanic crust (started forming about 4.5 billion years ago; granitic continental crust – started forming about 4.4 billion years ago).

Basalt formed at a mid oceanic ridge due to partial melting of peridotite.

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The answer involves cooler temperatures, the development of mid-oceanic ridges, subduction zones and partial melting*. As the earth cooled (around the beginning of the archean) and temperatures fluctuated, masses of mantle magma may have gone through cycles of solidifying and melting. The resulting magma may have been more basaltic (forms at a lower temperature and by partial melting* of peridotite). Modern Plate tectonics had begun, forming basaltic oceanic crust at mid-oceanic ridges. This resulted in cooler, larger, longer-lasting crustal rock slabs. These collided and were subducted and also underwent partial melting* – felsic minerals melt first and produce a more felsic magma and more felsic rocks (e.g. tonalite – a quartz-rich intrusive igneous rock) – recycling of these rocks made them more and more felsic until granitic rocks formed (still in the early Archean). When these early volcanic rocks grew above sea level (became land) they were eroded and formed the first sedimentary rock (greywackes, conglomerates) possibly as early as 4.4 billion years ago.

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To recap: basaltic oceanic crust formed first at mid-oceanic ridges and was probably wide-spread (all over the world); continental crust formed later as oceanic crust was subducted and partially-melted, releasing more and more felsic magma. This magma formed small patches of continental crust near subduction zones. When these patches grew above sea-level, they were eroded and produced the first sedimentary rocks.

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Greenstone Belts Evidence for these processes is found in GREENSTONE BELTS – which record increasingly felsic volcanic rocks, metamorphosed and topped by sedimentary rocks (also metamorphosed) (the metamorphic mineral chlorite is green – hence greenstone belts).The sedimentary rocks in the upper part of the sequence often contain conglomerates and greywackes, suggesting steep, rugged coastlines and the absence of shallow seas. All are intruded by later granites. The entire sequence records the changing conditions – cooling temperatures, more felsic rocks and the first appearance of sedimentary rocks.

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Continental crusts grew larger by much the same way as they do today:

•Small crustal slabs collided and became sutured together

•Continental growth by accretion occurred at subduction zones

•Sedimentation accumulated around the coastlines

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Hence, the early contiental crust consisted of greenstone belts, accretionary sediment wedges and suture zones where two crustal slabs had welded together.

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The Proterozoic (2.5 - 0.54 billion).

These processes continued into the Proterozoic, building the North American craton. So the craton is actually separate provinces, welded together - ages of the provinces get younger further out from the center. The Proterozoic is distinguished by more modern Tectonics and the first shallow marine rocks (formed on wide continental shelves).

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Therefore, it is probable that cratons developed in much the same way as more recent parts of continents i.e.

1. orogenesis forming mountains, folded and metamorphosed rocks (at subduction zones and suture zones).2. continental growth by accretion (many cratons consist of smaller continental masses, or provinces, joined together).3. Failed intracratonic rifting (e.g. mid continental rift – volcanic and sedimentary rocks)

The Proterozoic rocks, being younger, formed around the margins, and inbetween, the older archean cratons.

In contrast to the archean, prolonged sedimentation built wide continental shelves and coastal plains allowing sandstones and carbonates to form (the first appearance of shallow marine/lowland environments). Most proterozoic rocks have been subject to varying degrees of folding, metamorphism, orogenesis and erosion.

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The Wopmay Belt – example of a proterozoic orogenic belt.

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The shields (or cratons) of all major land masses have a similar history.

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In the late (Neo)proterozoic, nearly all land masses were brought together by plate movements to form a single continent – RODINIA, surrounded by an ocean MIROVIA. Rodinia included LAURENTIA – the Precambrian craton of North America – it was sutured to Rodinia by the Grenville Orogeny.