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- Recall that metamorphic rocks form when existing rocks are changed by
heat and pressure.
- Metamorphism means
- “ to change form”.
- Rocks produced during metamorphism often look much different from the
original parent rocks.
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- During contact metamorphism, hot
magma moves into rocks.
- Contact metamorphism often produces what is called low-grade
metamorphism, changes to rocks are minor
- Marble, like the marble used in Michelangelo’s sculpture of David, is a
common contact metamorphic rock.
- Marble often forms when magma intrudes on limestone.
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- During mountain building, large areas of rocks are
- subjected to extreme
pressures and temperatures.
- The intense changes produced during these processes are described as high-grade
metamorphism.
- Regional metamorphism
- results in large-scale
- deformation and high
- grade metamorphism.
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- The agents of metamorphism are:
- Heat
- Pressure
- Hydrothermal solutions
- During metamorphism, rocks are usually subjected to all three at the
same time.
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- The most important agent is heat.
- Heat provides the energy needed to drive chemical reactions.
- Some of these chemical reactions cause minerals to recrystallize;
changing their structure.
- Other reactions cause entirely new minerals to form.
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- The heat for metamorphism comes from two sources mainly:
- Magma
- Change in temperature with depth
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- Magma, molten rock deep within the Earth, causes metamorphism to happen
when it comes in contact with other cooler rock.
- Magma basically “bakes” whatever rocks it comes in contact with.
- Heat also comes from the gradual increase in temperature within the
crust.
- In the upper crust, this increase averages between 20 degrees centigrade
and 30 degrees centigrade per kilometer of change.
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- Pressure, like heat, also increases with depth.
- Like the water pressure you feel underwater when you swim in a pool, the
pressure on rocks in the Earth is applied in all directions.
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- Pressure on rocks causes the spaces between the mineral grains to close.
- The result is more compact rock with greater density.
- This pressure may also cause minerals to recrystallize into entirely new
minerals.
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- Increases in temperature and pressure cause rocks to flow rather than
fracture.
- Under these conditions, mineral grains tend to flatten and elongate.
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- During mountain building, horizontal forces caused by the collision of
plates metamorphose large parts of the Earth’s crust.
- This often produces intricate deep folds in the rocks.
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- Water solutions containing other substances that readily change to gases
at the surface play an important role in metamorphism.
- Solutions that surround mineral grains aid in recrystallization by
making it easier for ions to move.
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- When these hot water-based solutions escape from a mass of magma, they
are called hydrothermal solutions.
- As a result of contact with hydrothermal solutions, a change in a rock’s
overall composition may occur.
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- Like igneous rocks, metamorphic rocks can be classified by texture and
composition into two categories:
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- When rocks undergo contact metamorphism, they become more compact and
thus more dense.
- Under more extreme conditions, certain minerals will recrystallize.
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- Some minerals recrystallize with a preferred orientation, which is at
right angles to the direction of force.
- This alignment gives the rock a layered or striped appearance which we
call a foliated appearance.
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- A metamorphic rock that does not have a banded texture is called a nonfoliated
metamorphic rock.
- Most nonfoliated rocks contain only one mineral.
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- Marble, for example, is a nonfoliated rock made of calcite.
- When it’s parent rock, limestone, is metamorphosed, the calcite crystals
combine to form the larger interlocking crystals seen in marble.
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Notes
