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Rocks Ch. 6
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How Rocks Form ch. 6 sec. 1 What is a Rock?
a solid made of 1 or more minerals also can contain organic matter ex. Coal In which of Earth’s layers (crust, mantle, core) are rocks found? crust & mantle What is a rock? an aggregate of minerals, a group of minerals bound together, a solid composed of more than one mineral Can consist of mostly one mineral or several different minerals in varying quantities… also can contain organic matter ex. coal In which of Earth’s layers (crust, mantle, core) are rocks found? Crust & mantle… we generally see the rocks of the crust BrainPop 3 Types of Rocks
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What is a Rock? What are the 3 types of rock found in Earth’s crust?
igneous sedimentary metamorphic How do we classify these 3 types of rocks? according to how they formed cooling & hardening of hot, molten rock (magma) compaction & cementing of layers of sediments (rock fragments, plant & animal remains, minerals that settle out of solution onto lake/ocean bottoms, or water that evaporates & leaves behinds minerals) effect of heat & pressure on other rocks BrainPop 3 Types of Rocks
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The Rock Cycle What is the rock cycle? What causes the rock cycle?
gradual & continuous process that causes rocks to change from one form to another What causes the rock cycle? interactions between water, air, land What causes the rock cycle? interactions between water, air, land weathering, erosion, deposition, compressive forces, stretching forces, rubbing forces, heating, pressure Rock Cycle Movie
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The Rock Cycle ESRT pg. 6
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What Can Happen to Igneous Rocks?
1. Heat & pressure/ “metamorphism” metamorphic rock 2. Melt to form magma which solidifies igneous rock 3. Weathering & erosion form sediments which are deposited, buried, compacted, & cemented sedimentary rock 3 1 2
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What Can Happen to Sedimentary Rocks?
1. Heat & pressure/ “metamorphism” metamorphic rock 2. Melt to form magma which solidifies igneous rock 3. Weathering & erosion form sediments which are deposited, buried, compacted, & cemented sedimentary rock 3 2 1
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What Can Happen to Metamorphic Rocks?
1. Heat & pressure/ “metamorphism” new metamorphic rock 2. Melt to form magma which solidifies igneous rock 3. Weathering & erosion form sediments which are deposited, buried, compacted, & cemented sedimentary rock 1 3 2
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Igneous Rocks ch. 6 sec. 2 Igneous Rock Formation
How are igneous rocks classified? By mineral composition & texture What do igneous rocks form from? molten rock (magma/lava) or volcanic ash What happens as the material cools? crystals grow & interlock rate affects size of crystals What happens as the material cools? crystals grow & interlock, rate affects size of crystals…. Slow = large crystals, fast = small (or no) crystals Igneous Rock Formation Movie
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Igneous Rock Formation
How can we classify the magma/lava that forms igneous rocks? felsic large amounts of silica (& aluminum) small amounts of calcium, iron, magnesium thick, sticky, slow-moving (high viscosity) low density typically forms light-colored minerals mafic large amounts of iron & magnesium Small amounts of silica thinner, runnier (less viscous) high density typically forms dark-colored minerals Magma may be classified as felsic, mafic, or an intermediate form. Felsic magma: thick and slow moving (high viscosity… resistance to flow); large amounts of silica (SiO2) and small amounts of calcium, iron, and magnesium; typically hardens into rocks containing light-colored silicate minerals (ex. quartz and postassium/orthoclase feldspar) Mafic magma: hotter, thinner, more fluid; large amounts of iron and magnesium and smaller amounts of silica; typically hardens into rocks containing dark-colored silicate minerals (ex. amphibole/hornblende, augite, biotite)
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Magma may be classified as felsic, mafic, or an intermediate form.
Felsic magma: thick and slow moving (high viscosity… resistance to flow); large amounts of silica (SiO2) and small amounts of calcium, iron, and magnesium; typically hardens into rocks containing light-colored silicate minerals (ex. quartz and orthoclase feldspar) Mafic magma: hotter, thinner, more fluid; large amounts of iron and magnesium and smaller amounts of silica; typically hardens into rocks containing dark-colored silicate minerals (ex. hornblende, augite, biotite)
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Igneous Rock Formation
What are the 2 types of igneous rocks? intrusive & extrusive How do intrusive igneous rocks form? form from magma inside Earth cools slowly How does that affect the crystal texture (size)? medium to coarse (easily seen) How do extrusive igneous rocks form? form from lava (or ash) that has exited Earth cools quickly glassy (no crystals) to fine (not easily seen) can be vesicular What are the 2 types of igneous rocks? Intrusive (aka plutonic igneous rocks) & extrusive (aka volcanic igneous rocks) How do intrusive igneous rocks form? Form from magma inside Earth, Cools slowly How does that affect the crystal texture (size)? Medium to coarse (easily seen) b/c cools slowly which allow crystals more time to form How do extrusive igneous rocks form? Form from lava (or ash) that has exited Earth, Cools quickly How does that affect the crystal texture (size)? Glassy (no crystals) to fine (not easily seen) b/c cools quickly which does not allow crystals to form or if they do form, they do not have time to get big… Can be vesicular (holes due to air bubbles that were trapped or burst during formation) Igneous Rock Formation Movie
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Igneous Rock Descriptions
How do we group igneous rocks into different “families”? according to mineral composition How can we recognize/ID specific igneous rocks? color determined by mineral composition texture size & arrangement of crystals
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Igneous Rock Descriptions
Granite Family/Felsic Rocks What is the composition of felsic magmas? silica (& aluminum) thick, sticky, slow-moving (high viscosity) What minerals are typically found in felsic rocks? quartz, feldspar, mica, amphibole/hornblende What are other common characteristics of felsic rocks? light color low density Examples: pegmatite, granite, obsidian, pumice, rhyolite Granite Family/Felsic Rocks Form from felsic (silica SiO2 and aluminum-rich) magmas Usually coarse-grained because their slow-rising, “sticky” parent magmas tend to cool slowly underground Typically contain quartz, feldspar, mica, amphibole/horneblende, Light-colored, Low in density Granite: one of the coarsest-grained rocks in this family Intrusive Often contain large amounts of light-colored feldspar color of feldspar determines rock color white or gray to pink Very common continental rock found in many mountainous areas across the U. S. Obsidian: Glassy texture (no crystals) Extrusive Chemically similar to granitic rocks even though it is usually dark brown or black (when thick, thin slices appear lighter) Pumice: Forms when silica-rich lava Extrusive hardens as steam & other gases bubble out of it causing Vesicular texture Resembles a sponge because of holes and air pockets Often able to float on water Felsite: General name for any light-colored, fine-grained rock Rhyolite is a common example Fine-grained, ranges from light gray to pink
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Igneous Rock Descriptions
Gabbro Family/Mafic Rocks What is the composition of mafic magmas? iron and magnesium-rich (silica poor) thinner, runnier (less viscous) What minerals are typically found in mafic rocks? pyroxene, olivine, plagioclase feldspar (amphibole & biotite mica) What are other common characteristics of mafic rocks? dark color high density Examples: gabbro, basalt, diabase, basaltic glass, scoria Gabbro Family/Mafic Rocks Form from mafic (iron and magnesium-rich/silica poor) magmas Typically contain pyroxene, olivine, plagioclase feldspar (amphibole and biotite mica) Dark in color High density Gabbro: coarse-grained rock very dark color Basalt: Composition similar to gabbro fine-grained, dark gray or black Most common rock in gabbro family On land (including underwater), most common rock Makes up the ocean floor formed from lava flows Diabase: texture is finer than gabbro but coarser than basalt Basalt glass: resembles obsidian but is mafic Scoria: (like pumice) full of holes, darker and denser than pumice, holes are usually larger, unlikely to float
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Igneous Rock Descriptions
Diorite Family/Intermediate Rocks What is the composition of intermediate magmas? neither felsic or mafic… has characteristics of both What are other common characteristics of mafic rocks? intermediate color medium grays & greens darker than felsic, lighter than mafic medium density Examples: diorite & andesite Diorite Family/Intermediate Rocks Diorite: coarse-grained, has less quartz than granite and less plagioclase feldspar than gabbro Andesite: fine-grained Other Igneous Rocks Felsic-intermediate: granodiorite Ultramafic: peridotite, dunite, pyroxenite Hypothesized to be similar to rocks in Earth’s mantle
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Identifying Igneous Rocks
Start w/ texture/grain size (& if vesicular or not) to narrow down & help determine if intrusive or extrusive Then look at color (light, in between, dark) & mineral composition (and approximate percentages if needed using ruler along left to help gauge percent/range of percents of each mineral type) Ex. Coarse, non-vesicular texture light-medium color contains pink, white/colorless, black minerals feldspar, quartz, biotite, amphibole
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Igneous Intrusions Dike: vertical, in between rock layers
Laccolith Volcanic neck Sill Volcano Batholith Stock Dike Pluton: any rock mass that forms when magma pushes into fractures (cracks) in the bedrock Examples: Dike: vertical, in between rock layers Sill: parallel to rock layers it intrudes Ex. Palisades Sill along the Hudson River (NY/NJ) Laccolith: domed mass, bulge Volcanic neck: central plug of hardened magma left after the volcanic material around it has worn away Batholith: largest of all plutons, cores of many mountains Stock: a small batholith that is exposed at the surface
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Sedimentary Rocks ch. 6 sec. 3 Formation of Sedimentary Rocks
Where are most sedimentary rocks found? covering the surface of Earth’s crust In general, how do sedimentary rocks form? compaction & cementing of layers of sediment How are sedimentary rocks classified? by 3 basic formation processes What are the 3 major types of sedimentary rocks? clastic chemical organic
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Clastic Sedimentary Rocks
How are clastic sedimentary rocks formed? weather forms fragments of rock (sediments) Usually eroded (transported) by running water sediments are deposited layer after layer as the water slows down sorted by largest sediments first, smallest last Why? compacted as layers pile up cemented together by minerals (dissolved in water) cement influences color (silica, calcite, iron oxide, clay) Sorted by largest sediments first, smallest last Why? As energy decreases (usually due to decrease in speed) largest/heaviest particles are first to be dropped b/c can still carry smaller/lighter particles… as slow down more & more, medium then small particles drop out
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Deposition & Sorting of Sediments
If given velocity… see where intersects w/ line on graph…. And look to left/right to find largest particle size that the water can carry (and all sizes below) If given particle size… see where intersects w/ line on graph…. & look down to see lowest velocity at which that particle size can be carried If given velocity, see where intersects w/ line on graph…. look to left/right to find largest particle size that the water can carry (& all sizes below) If given particle size, see where intersects w/ line on graph…. look down to see lowest velocity at which that particle size can be carried
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Clastic Sedimentary Rocks are Classified by Particle Size
Smallest to largest silt & clay particles shale/siltstone sand particles sandstone mixed particles conglomerate/ breccia
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Chemical Sedimentary Rocks
How are chemical sedimentary rocks formed? when minerals precipitate (fall out) of water What cause mineral precipitation? evaporation sea or lake dries up leaving behind minerals that were dissolved in water chemical action dissolved ions combine to form new minerals left: salt flats right: the white cliffs of Dover (England) made of limestone Also referred to as crystalline sedimentary rocks
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Chemical Sedimentary Rocks
Examples: Rock Salt Rock Gypsum Limestone (travertine)
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Organic Sedimentary Rocks
How are chemical sedimentary rocks formed? from sediments consisting of the remains of plants and animals Examples of organic sedimentary rocks limestone (& coquina) coal Limestone contain mineral calcite Begins when water dissolves calcite out of rocks on land & carries it in the form of calcium ions to ocean or lake Certain organisms use the ions to produce calcium carbonate shells or other support structures When die, remains pile up on ocean floor Masses of complete & nearly complete shells can be cemented together (coquina) Small shell fragments cemented together limestone
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Organic Sedimentary Rocks
Shells Fossil limestone Contain the mineral calcite
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Organic Sedimentary Rocks
Plant remains coal peat lignite bituminous anthracite
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Features of Sedimentary Rocks
stratification fossils ripple marks mud cracks nodules concretions geodes Stratification arrangement of visible layers result from changes in sediment type being deposited Bedding planes (lines between the layers) show where the layers are separated Usually horizontal, but cross-bedding (angled deposits) can occur Occur for a number of reasons New types of rocks picked up (from different locations) More of different types of rocks carried during flooding Sediments carried longer or shorter distances Fossils the remains, impression, or other evidence of a plant or animal preserved in rock occur when dead organism is buried by sediments and gradually turns to rock Usually only hard parts are preserved Impressions occur when shell, skeleton, etc. is pressed into soft sediments Ripple marks = sand patterns formed by the wind, streams, waves, or currents Mud cracks = develop when wet clay dries and contracts (shrinks) Cracks fill with different sediments & fossilize Nodules = lumps of fine-grained silica in limestone or chalk Ex. chert and flint Concretions = round, solid masses of calcium carbonate form when minerals in dissolved in water precipitate around shell fragments or other impurities in clay sediments Ex. Oolites Geodes = spheres of silica rock found in limestone Inside lined or filled with crystals (quartz or calcite)
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Identifying Sedimentary Rocks
1st, determine texture (clastic, crystalline, bioclastic) 2nd, if clastic…. grain-size & comments if crystalline, try to determine mineral composition (halite looks & tastes like salt, dolomite when powdered, bubbles in acid, gypsum generally looks powdery & white/beige/pink) if bioclastic… comments…. (shells? Fossils? Plant remains?) try to determine mineral composition (calcite bubbles in acid, carbon generally dark in color)
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Metamorphic Rocks ch. 6 sec. 4 Formation of Metamorphic Rocks
In general, how do metamorphic rocks form? formed from “parent rock” that has undergone metamorphism pressure & heat Earth’s internal heat weight of overlying rock deformation of rock as mountains build moisture hot liquids (& gases) from magma that react with minerals
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Formation of Metamorphic Rocks
How do metamorphic rocks compare to parent rocks? may resemble parent rock may have a chemical composition, texture, or internal structure that differs from parent rock minerals may be enlarged or reformed new minerals may appear rock may become more dense & less porous (less “empty” space) Often resembles “parent rock” Differences are the result of metamorphic processes that the “parent rock” has undergone A metamorphic rock may have a chemical composition, texture, or internal structure that differs from the parent rock. Minerals may be enlarged or reformed New minerals may appear The rock may be more dense and less porous (less “empty” space)
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Metamorphic Processes
What are the 2 basic types of metamorphism? regional local Metamorphism the process by which a rock’s structure is changed by pressure, heat, moisture
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Metamorphic Processes
What is regional metamorphism? Large-scale intense heat & pressure (ex. mountain building) pressure greater in one direction minerals align in layers (perpendicular to force) can cause folding of rock layers Limestone Marble gneiss schist phyllite slate shale Lime quartzite sandstone Metamorphism the process by which a rock’s structure is changed by pressure, heat, moisture Regional Forms most of the metamorphic rock of Earth's crust Often occurs over very large areas Can occur during mountain building Due to intense heat and pressure Temperature increases with depth Pressure increases w/ depth (more overlying rock) Pressure greater in 1 direction, minerals align in layers Different amounts of heat & pressure different amounts of metamorphism. Higher temperature & pressure greater metamorphism Can cause folding of rock layers forms most of the metamorphic rock of Earth's crust
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Metamorphic Processes
What is local metamorphism? occurs over smaller, more distinct areas than regional two types contact hot magma “bakes” rock deformational (dynamic) low temperature, but high pressure areas of stress & friction ex. plate boundaries changes to texture & structure of minerals (not composition) Local Smaller, more distinct areas Two types Contact: Occurs when hot magma moves into rock, heating and changing it. Causes fewer changes and affects much less rock than regional metamorphism Deformational (aka dynamic): Occurs at relatively low temperatures and high pressure Caused by stress and friction (often at faults where rocks move against each other)… mountain building, transform plate boundaries Mineral composition usually stays the same, but texture and structure may change
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Metamorphic Rock Descriptions
description & ID usually based on texture, grain size, mineral content, & parent rock 2 main types foliated mineral alignment (due to pressure) often different colored bands (“banding”) may look scaly often split along parallel layers non-foliated don’t show mineral alignment or banding look crystalline (sparkly or sugary) Description and identification usually based on parent rock, mineral content, and texture Foliated Metamorphic Rocks Minerals flattened by pressure producing mineral alignment at 90 degree angle to direction of pressure, may also cause minerals to differentiate into different colored bands Nonfoliated Metamorphic Rocks don’t show mineral alignment or banding look crystalline (sparkly or sugary)
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Foliated Metamorphic Rocks: Examples
granite gneiss shale slate phyllite schist (Extreme Metamorphism)
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Non-foliated Metamorphic Rocks: Examples
Limestone marble Sandstone quartzite Conglomerate metaconglomerate
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Identifying Metamorphic Rocks
1st determine texture 2nd determine grain size 3rd, if possible, determine mineral composition 4th, use comments to help make final ID if necessary
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