3.1 The Rock Cycle

Make a cycle diagram of the rock cycle using the following terms: -Sedimentary rock -Igneous rock-Metamorphic rock -Magma -Lava -Sediment-Heat and pressure-Weathering, erosion, and deposition-Cementation and compaction-Melting -Cooling

Rocks

3.1 The Rock Cycle

Rocks are any solid mass of mineral or mineral-like matter occurring naturally as part of our planet.

Types of Rocks

1. Igneous rock is formed by the crystallization of molten magma.

Rocks

3.1 The Rock Cycle

Types of Rocks2. Sedimentary rock is formed from the

weathered products of preexisting rocks that have been transported, deposited, compacted, and cemented.

3. Metamorphic rock is formed by the alteration of pre-existing rock deep within Earth (but still in the solid state) by heat, pressure, and/or chemically active fluids.

The Rock Cycle

3.1 The Rock Cycle

Shows the interrelationships among the three

rock types (igneous, sedimentary, and metamorphic)

Magma is molten material that forms deep beneath the Earth’s surface.

Lava is magma that reaches the surface. Weathering is a process in which rocks are

broken down by water, air, and living things. Sediment is weathered pieces of Earth

elements.

Energy That Drives the Rock Cycle

3.1 The Rock Cycle

Processes driven by heat from the Earth’s interior are responsible for forming both igneous rock and metamorphic rock.

External processes produce sedimentary rocks.

Weathering and the movement of weathered materials are external processes powered by energy from the sun.

The Rock Cycle

Figure 2: The rock cycle consists of many processes that change Earth’s rocks.

Q: Can a sedimentary rock become an igneous rock without changing first to a metamorphic rock?

The Rock Cycle

1. What processes form sedimentary rocks?

2. What possible changes might a sedimentary rock undergo?

3. What type of rock is formed by cooling magma and lava?

4. What happens to igneous rock that is weathered?

3 Types of Rocks

Igneous Sedimentary Metamorphic Formation Formation Formation

Classification Classification Classification

Formation of Igneous Rocks

3.2 Igneous Rocks

1. Intrusive igneous rocks are formed when magma hardens beneath Earth’s surface.

2. Extrusive igneous rocks are formed when lava hardens.

Classification of Igneous Rocks

3.2 Igneous Rocks

Igneous rocks can be classified based on their composition and texture.

Classification of Igneous Rocks

3.2 Igneous Rocks

1. Texture• Coarse-grained texture is caused by slow

cooling resulting in larger crystals.

• Fine-grained texture is caused by rapid cooling resulting in smaller, interconnected mineral grains.

• Glassy texture is caused by very rapid cooling.

• Porphyritic texture is caused by different rates of cooling resulting in varied sized minerals.

Classification of Igneous Rocks

3.2 Igneous Rocks

2. Composition• Granitic composition rocks are made mostly

of light-colored quartz and feldspar.

• Basaltic composition rocks are made mostly of dark-colored silicate minerals and plagioclase feldspar.

• Andesitic composition rocks are between granitic light-color minerals and basaltic composition dark-colored minerals.

• Ultramafic composition rocks are made mostly from iron and magnesium-rich minerals.

Igneous Rocks

A: Granite is an intrusive igneous rock that forms when magma cools slowly beneath Earth’s surface. B: Rhyolite is an extrusive igneous rock that forms when lava cools quickly at Earth’s surface. 1.In what ways are the two rocks similar? 2.In what ways are the two rocks different?

Obsidian Exhibits a Glassy Texture.

Obsidian is an example of a rock that does not have a crystalline structure.

Porphyritic Igneous Texture

This sample of andesite displays igneous rock with a porphyritic texture.

Describe how this rock probably formed.

Basalt

Basalt is an igneous rock made mostly of dark-colored silicate materials.

Describe the texture of the igneous rock.

Formation of Sedimentary Rocks

3.3 Sedimentary Rocks

• Erosion involves the weathering and the removal of rock.

• Deposition occurs when an agent of erosion—water, wind, ice, or gravity—loses energy and drops sediments.

Weathering, Erosion, and Deposition

Formation of Sedimentary Rocks

3.3 Sedimentary Rocks

• Compaction is a process that squeezes, or compacts, sediments.

• Cementation takes place when dissolved minerals are deposited in the tiny spaces among the sediments.

Compaction and Cementation

Classification of Sedimentary Rocks

3.3 Sedimentary Rocks

1. Clastic sedimentary rocks are composed of weathered bits of rocks and minerals.

• Classified by particle size

Two Main Groups

- Shale (most abundant)• Common rocks include

- Conglomerate

- Sandstone

Classification of Sedimentary Rocks

3.3 Sedimentary Rocks

Two Main Groups2. Chemical sedimentary rocks form when

dissolved substances precipitate, or separate, from water. • Common rocks include

- limestone—most abundant chemical rock

- microcrystalline quartz known as chert, flint, jasper, or agate

- evaporites such as rock salt or gypsum - coal

Conglomerate

Shale with Plant Fossils

Fossiliferous Limestone

Features of Some Sedimentary Rocks

3.3 Sedimentary Rocks

Features of sedimentary rocks are clues to how and where the rocks are formed

Formation of Metamorphic Rocks

3.4 Metamorphic Rocks

Metamorphism means “to change form.”

Conditions for formation are found a few kilometers below the Earth’s surface and extend into the upper mantle.

Most metamorphic changes occur at elevated temperatures and pressures.

Formation of Metamorphic Rocks

3.4 Metamorphic Rocks

Contact metamorphism occurs when magma moves into rock.

• Changes are driven by a rise in temperature.

• Occurs near a body of magma

Formation of Metamorphic Rocks

3.4 Metamorphic Rocks

Regional metamorphism results in large-scale deformation and high-grade metamorphism. • Directed pressures and high temperatures

occur during mountain building.

• Produces the greatest volume of metamorphic rock

Agents of Metamorphism

3.4 Metamorphic Rocks

Heat

Pressure

• Provides the energy needed to drive chemical reactions

• Causes a more compact rock with greater density

Origin of Pressure in Metamorphism

Forces in all directions are applied to equally buried rocks. During mountain building, rocks subjected to differential stress are shortened in the direction that pressure is applied.

Agents of Metamorphism

3.4 Metamorphic Rocks

• Hot water-based solutions escaping from the mass of magma

• Promote recrystallization by dissolving original minerals and then depositing new ones

Hydrothermal Solutions

Classification of Metamorphic Rocks

3.4 Metamorphic Rocks

1. Foliated Metamorphic Rock

2. Nonfoliated Metamorphic Rock

Two main categories

• Has a banded or layered appearance

• Does not have a banded texture

Gneiss Typically Displays a Banded Appearance

Marble—A Nonfoliated Metamorphic Rock

Classification of Rocks

Table 1 pg. 741.Which rocks have the highest percentage of dark minerals? 2.Identify a coarse-grained basaltic rock. 3.What minerals are in granite? Table 2 pg. 791.How does the texture of gravel compare with that of sand? 2.What type of detrital sedimentary rock has a very fine texture? 3.What is the chemical composition of chalk? 4.Which chemical sedimentary rock is made up of halite? Table 3 pg. 841.What is the parent rock of schist? 2.Which has undergone more intense metamorphism, slate or gneiss? Explain your answer. 3.Which non-foliated rock has the finest grains?

Classification of Igneous Rocks

Classification of Sedimentary Rocks

Classification of Metamorphic Rocks