Lecture 4- Igneous Rocks and Processes

Lecture 4- Igneous Rocks and Processes

Geology in the news

• 3.7 Ga fossil found in Greenland
• Possibly the oldest life form ever found

Magma

• Magma
• Molten lava
• Underground
• Lava
• Above ground
• Melting process
• How to melt Rock
• 1- temperature
• Partial melting
• At any given temperature on component will melt and the others will remain solid
• B/c different minerals w/ different melting points
• Wet melting
• If a lot of water is added to the reaction, the water will lower the melting point
• Fills up cracks and fractures and crystal structures
• Permeate the entire body
• Decompression Melting
• If pressure is decreased, the melting point is lower
• Magma Composition
• Gases
• SiO2
• 3 main types
• Basaltic Magma
• Most common type of magma
• Dry magma
• Very little water content
• SiO2 content 50% (defining component)*
• >1100° C (hottest type of magma)
• 1800° F
• Andesitic Magma
• Andesite Line aka Ring of Fire
• More rare
• Gets generated in subduction zones
• Magma gets other types of minerals added as it flows to surface, changing the composition
• SiO2 60%
• Rhyolitic Magma
• 700°-800° C (lowest)
• Shallow
• Only found in continental crust
• Wet Magma
• Higher water content
• SiO2- 70% (highest)

Study Hint

Understand how all those properties are linked instead of memorizing

• Freezing of Magma
• Crystallization
• Taking the liquid and turning it into a solid (freezing)
• Partial Freezing
• Some components are frozen before others
• Two things could occur
• Equilibrium Crystallization
• There’s no change in the chemistry as the magma is frozen
• Nothing is added or subtracted
• More rare
• Fractional Crystallization
• Some fraction of the composition changes as it is frozen
• Adding or subtracting something
• No longer chemically identical to original
• More common
• Minerals form in a specific order as magma cools
• Bowens Reaction Series
• Discontinuous Branch
• Left hand branch and the stem
• As the temperature decreases, a mineral is formed and then stopped and another mineral is formed and then stopped as the temperature changes
• Ex: cars
• 2015 models, then discontinued and in 2016 make 2016 models
• Continuous branch
• Right hand side
• Wide temperature range
• Plagioclase is formed throughout the process but the composition is changing
• As the temperature changes, substitutions are added
• Still same mineral but different composition (changes the ratio)
• Continuous reaction
• Both discontinuous and continuous branch can happen at same time

Igneous Rocks

• Two broad types
• Plutonic (Intrusive)
• Forming below the surface of the earth
• Volcanic (extrusive)
• Form above the surface
• Two properties needed for ID:
• Texture
• Size of the mineral crystals
• Composition
• Which minerals are present
• Plutonic Rocks
• Magma flows toward surface but doesn’t make it (blocked or cools down)
• Plutons
• Any large body of plutonic rock
• Types
• Dikes and Sill
• Long pipe-like
• Fault like or crack
• Dike are vertically oriented
• Cut through layers
• Sills are Horizontally oriented
• In between layers
• Laccolith
• Magma get stuck as it works it way up
• Pimped shaped
• Cause rocks above it to warp but never makes way through
• May be able to see they exposed at surface later on due to weathering or other
• Batholith
• Blobby, no distinct shape
• Largest bodies
• Texture of Intrusive Rocks
• Pegmatitic (Pegmatite)
• Crystals are very large
• Ex: larger than fingernail
• Phaneritic
• One size notch down from pegmatitic
• 1cm and smaller
• Large still
• Composition
• Two ways
• Identify each mineral w/in rock
• Color Index
• % of light and dark minerals w/in rock
• It’s a shortcut than can fail
• Works about 90% of the time
• Felsic
• Dominated by light color minerals
• Intermediate
• Grey composition
• Mafic
• Dominated by brown and black minerals
• Ultramafic
• Green and yellow minerals
• Volcanic Rocks
• ID with the same traits- texture and composition
• Same conditions apply
• Texture (Extrusive Rocks)
• Porphyritic
• Some grains that are large enough to see and some that are too small to see
• Phenocrysts
• Large crystals
• Below ground
• Ground mass
• The little stuff that looks homogenous
• Above ground
• Cooled slowly crating the big crystals and then some lava came up and had to cool fast creating little stuff
• Aphanitic
• All the crystals are too small to see w/o magnification
• Formed rapidly
• Glassy
• All of the specimens look like they are made of glass
• Large reflective surface
• Vesicular
• Having bubbles or pockets throughout the structure
• Tiny craters
• A lot of the gas trapped in lava until the last stage of cooling
• Has to be many pockets
• Volcanoes
• Misconception
• The US doesn’t have to worry about volcanoes
• Japan and Indonesia are the only countries with more volcanoes than the US
• Active Volcanoes in US
• Hawaii= 7
• Alaska= 41
• Contiguous 48 States= 20
• Case Study
• Krakatoa
• Indonesian volcano
• Aug 26, 1883
• 200 million tons TNT= 13,000x the yield of the Hiroshima A-bomb (VEI 6)
• 25 cubic km of ejecta
• Heard>3,000 mi away
• Air pressure waves circled the globe for 5 days, caused waves in the English channel
• Over 30,000 dead, several languages went extinct
• 2/3 of island destroyed, new volcano built up
• Volcano Explosively Index (VEI)
• Categorize how explosive a volcanic eruption was
• Explosive v Non-explosive
• Magma Properties
• Viscosity
• The ability to flow
• Resistance to flow= high viscosity ex: peanut butter
• Controlled by two main things
• 1- Temp
• The higher the temp the lower the viscosity, the lower the silica content
• 2- Silica Content
• High silica content -> high viscosity
• Controls gas content
• High pressure= more dissolved gas
• Non-Explosive features
• Pahoehoe
• Lava is starting to crust over at surface but still soft and squishy right underneath
• Aa
• Almost finished cooling down
• Close to being a solid
• Rocky appearance
• Vesicles
• Tiny holes where magma is escaping at last minute
• How fast does lava actually flow
• 16 km/hr or 10 mph
• Explosive Eruptions
• Several hazards beyond lava
• Lahar
• A mud flow (mudslide) that’s associated with a volcano that is erupting or about to erupt
• Pyroclasts
• All the solid debris that get blown out of volcano
• Chunks of rock
• Crystals and minerals
• Divided by size
• Bombs >64mm
• Lapilli 64-2mm
• Ash <2mm
• Pyroclastic Flow
• All the solid debris gets trapped inside cloud of volcanic gases that rises and then falls
• Can move very quickly
• Different types of volcanoes based on type of eruption and erupted material
• Shield Volcano
• Captain America shield shape
• Most common
• Basaltic magma
• Gives shield shape, so fluid (low viscosity) it can extend over a long distance
• Tephra (cinder) cone
• Steeper
• Small most of the time
• Pyriclastic (solid debris) debris
• Nothing to help fuse into solid rock and therefore can only make so fall w/o falling or rolling down
• Can form around or in the surrounding area of another volcano
• Statocones
• Composite volcanoes or stratovolcano
• Very tall, steep, and mountainous looking
• What we think of volcanoes
• Higher viscosity
• Pyroclastic material that can be fused together by the lava to build up the volcano
• Supervolcanic Eruptions
• Large enough to have an impact on a global scale
• Very few
• Tambora (1815) 100 km^3 eject
• Upset global weather patterns into the next year
• Yellowstone Huckleberry Ridge eruption
• 2 Ma, 2500 km^3 ejecta
• Hot Spots
• The Hawaiian Problem
• An area below the lithosphere where there is a lot of magma continuously making its way to the surface over time
• As the plate moves, it opens up a “vent” for the hotspot that’s rooted deep in the earth