Fig. 03.01
Fig. 03.02
Magma: molten rock + volatiles beneath the Earth’s surface.
Lava: molten rock on the Earth’s surface that has lost at least some of its volatiles.
Magma is usually silicate in composition: ~50-70 wt% SiO2
The rest is made up of Al2O3, Fe2O3, FeO, Na2O MgO, K2O, CaO, P2O5, TiO2
A continuous range of magma chemistries is observed.
Partial Melting
Rocks rarely melt to 100%.
Rocks contain several minerals – the one with the lowest melting point melts first and that with the highest melts last.
Liquid may be removed along grain boundaries.
This can create a magma of a different composition than the source material.
Fig. 03.06
Table 03.01
Felsic~70 wt% SiO2
Intermediate~60 wt% SiO2
Mafic~50 wt% SiO2
Ultramafic<50 wt% SiO2
(Komatiite)
Fig. 03.07a
Fig. 03.07b
Fig. 03.07c
Fig. 03.07e
Fig. 03.07f
General Rules
Felsic = light-colored (Si-, Al-, alkali-rich).
Ultramafic and Mafic = dark-colored (Fe, Mg, Ca rich, ferromagnesian mineral-rich).
Magmatic temperatures range from ~600˚C to >1,500˚C.
The Exception that Proves the Rule - Obsidian
Obsidian = felsic (quenched glass), but black.
General Textures & Crystallization
Rate of crystallization dictates mineral size: slow cooling = large crystals; fast cooling = small crystals or a quench glass.
General Textures
Extruded or erupted magmas or shallowly emplaced magma bodies cool quickly many small, interlocking crystals with some interstitial quench glass.
Intrusions of magma deeper within the crust are insulated. Although the margin of the magma next to the wallrock is chilled (small grain size) and the wallrock is baked, the interior of the magma cools much more slowly = large grain size (phaneritic).
Deep intrusive igneous rocks are give the generic term “plutonic”.
Fig. 03.05a
Plutonic Rock (Granite)
Fig. 03.05b
Plutonic Rock (Granite) in Thin Section
Fig. 03.03
Plutonic Rock (Granite) in the Field
Textural TermsAPHANITIC: individual crystals are so small they cannot be discerned with the naked eye. Common in eruptive and shallow intrusive igneous rocks.
PHANERITIC: crystals can be seen, common in interiors of thick flows and deeper intrusions.
Textural Terms
PORPHYRITIC: large crystal (PHENOCRYSTS) in a fine-grained groundmass. Reflects two cooling stages – slow cooling (in a magma chamber) to form the phenocrysts, followed by rapid cooling as would occur upon eruption.
Textural Terms
Textural Terms
PEGMATITIC: contains very large (cm-size) crystals.
Crystal Shapes
EUHEDRAL: well-formed crystals with many crystal faces developed.
Crystal ShapesSUBHEDRAL: crystals with only a few
crystal faces developed.
Crystal ShapesANHEDRAL: crystals with no crystal faces
developed.
Magma Viscosity
Magma viscosity is dependent upon composition and temperature:
Mafic << Felsic Hot << Cool
Silica affects viscosity because of poly-merization or linking of SiO2 tetrahedra.
The more silica-rich the more felsic the magma is and the stickier it is.
Magma ViscosityAll magmas contain gases, but felsic magmas are generally more gas-rich - explosive.When gases escape, can form vesicular lavas, e.g., vesicular basalt:
Pumice = “froth” = felsic.
Intrusive RocksIntrude older rocks (generically known as “countyrock” – can be igneous, sedimentary, or metamorphic) and bake them = contact metamorphism.
Intrusive rocks recognized by:
Intrusive Rocks
Coarse grain size, interlocking crystals, typically lacking a fabric (oriented texture).
Baked contacts (country rock) and chill zone (finer grain size) at the edges of the intrusion.
Inclusions of country rock = “xenoliths”.
They cross-cut features in the country rock.
Veins protrude outward into country rock.
Fig. 03.04
Ship Rock, New Mexico
Fig. 03.08b
Fig. 03.13
Fig. 03.12
Fig. 03.14
Granite Batholith, Sierra Nevada
Fig. 03.10
How to distinguish a sill from a flow:
• baked contacts above and below;• vesicles (gas bubbles) in flow often
filled in with flows;• smaller dikes present above sill
intruding the overlying countryrock.
Intrusion Types
Changing a Magma Composition
Fractional crystallization via crystal settling:
Changing a Magma CompositionMixing of two compositionally distinct magmas:
Changing a Magma Composition
Assimilation of country rock:
Changing a Magma Composition
Partial melting of the source rock to different degrees.
Plate Tectonics & Igneous Rocks
Divergent Plate Margins – lithosphere and asthenosphere; pressure-release, almost all mafic magmatism.
Plate Tectonics & Igneous Rocks
Intraplate: Hawaii, Yellowstone, LIPs – mantle plume activity.
Fig. 03.24
Plate Tectonics & Igneous Rocks
Convergent Plate Margins: more intermediate and felsic magmatism, especially if volcanoes are built on continents.
Fig. 03.26
Origin of Granite: magmatic underplating.