Basic Igneous Rocks
Mafic and Felsic Both are made-up terms used to indicate the chemical composition of silicate minerals, magmas, and igneous rocks.
Mafic refers to silicate crystals, magmas, and rocks with a high proportion of heavier elements. The name "mafic magma" comes from the combination of the letters MA and FIC, which stand for magnesium and iron in Latin. Mafic magmas are also high in calcium and sodium. Mafic minerals are usually dark in color with high specific gravities (greater than 3.0). Olivine, pyroxene, amphibole, biotite mica, and plagioclase feldspars are common rock-forming mafic minerals. Mafic magmas are typically formed at spreading centers and represent newly differentiated upper mantle material. Basalt and gabbro are examples of mafic rocks. (It should be noted that certain geologists with dubious intentions reverse the magnesium and iron order and coin the name "femag.") This is not to be confused with Femag, the Diabolical Dr. Saprolite's dimwitted henchman.)
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Felsic rock like the one shown above, on the other hand, refers to silicate crystals, magmas, and rocks with a smaller proportion of heavier elements and a higher concentration of lighter elements including silicon and oxygen, aluminum, and potassium. The word is derived from FEL, which stands for feldspar (in this case, the potassium-rich variety), and SIC, which stands for silica content. Felsic minerals have a light color and a basic gravity of less than 3.0. Quartz, muscovite mica, and orthoclase feldspars are common felsic minerals. Granite, the refined result of the earth's internal separation process, is the most common felsic rock.
Felsic and mafic rocks are igneous rocks classified according to their silica content. Chemical analysis of the most abundant components in rocks are commonly presented as oxides of the elements; igneous rocks generally contain about 12 major oxides, which account for over 99 percent of the rock. Silica (SiO2) is normally the most prevalent of the oxides. Due to this abundance and the fact that silicates make up the majority of igneous minerals, silica content was used as a basis for early classifications, and it is still generally accepted today. Rocks are classified as felsic, intermediate, mafic, or ultramafic according to this scheme (in order of decreasing silica content).
Rocks with more than 65 percent silica are felsic; those with 55 to 65 percent silica are intermediate; those with 45 to 55 percent silica are mafic; and those with less than 45 percent are ultramafic, according to a generally recognized silica-content classification scheme. Rhyolite and granite are felsic rocks, with an average silica content of 72 percent; syenite, diorite, and monzonite are intermediate rocks, with an average silica content of 59 percent; gabbro and basalt are mafic rocks, with an average silica content of 48 percent; and peridotite is an ultramafic rock, with an average silica content of 41 percent. Despite the fact that the averages have full gradations, rocks appear to cluster around them. The transition from felsic to mafic is generally accompanied by a rise in the color index (dark-mineral percentage).
Classification of Felsic Rocks
A rock must contain >75 percent felsic minerals, such as quartz, orthoclase, and plagioclase, in order to be categorized as felsic. Rocks that contain more than 90% felsic minerals are known as leucocratic, which means 'light-colored.'
Felsite is a petrologic word for fine-grained or aphanitic light-colored volcanic rocks that may be reclassified after a more thorough microscopic or chemical examination.
Some felsic volcanic rocks contain phenocrysts of mafic minerals, such as hornblende, pyroxene, or a feldspar mineral, and must be named after the phenocryst mineral, such as 'hornblende-bearing felsite.'
The TAS diagram of Le Maitre is used to determine the chemical name of a felsic rock (1975). This, however, is only true of volcanic rocks. If the rock is felsic yet metamorphic and lacks a definite volcanic protolith, it may be appropriate to simply refer to it as a 'felsic schist.' Extremely sheared granites that can be mistaken for rhyolites have been discovered.
The QAPF diagram should be used for phaneritic felsic rocks, and a name should be given according to granite nomenclature. Since the term granite already assumes feldspar and quartz, species of mafic minerals are often included in the name, such as hornblende-bearing granite, pyroxene tonalite, or augite megacrystic monzonite.
Mafic vs Felsic
Two terms are widely used to describe the characteristics of rocks and lava in the concept of mineralogy, or geology in a wider context. The terms mafic and felsic are used to describe these types of rocks.
1. Sticky or Runny
Mafic lava is runnier or more viscous than felsic lava when used to characterize its characteristics.
The amount of silica in the lava is the explanation for this. Mafic lavas have less silica than felsic lavas. The volcanic eruption would most likely be less violent than the Hawaiian Island volcanic eruptions due to the runnier lava.
Summary: Mafic vs Felsic
1. Mafic lava is viscous compared to felsic lava.
2. Mafic lava dominates mid-ocean ridges, while felsic lava is found mostly at convergent areas.
3. Mafic lava flows more easily than felsic lava, and the former has a lower risk of exploding. Since felsics tend to cap steam and other gases, explosive eruptions are more likely.
4. Basalt is formed by mafic lava, while andesitic and rhyolite are formed by felsic lava.
5. When discussing rocks or lava, mafic means the lava or rock contains less silica, while felsic means the lava or rock contains the most silica.
6. Mafic rocks are darker than felsic rocks in color.
FAQs on Felsic and Mafic
1. What is the main difference between felsic and mafic rocks?
The primary difference lies in their chemical composition, which affects their colour and density. Felsic rocks are rich in lighter elements like silicon and aluminium, making them typically light-coloured and less dense. In contrast, mafic rocks are rich in magnesium and iron (ferric), which makes them dark-coloured and denser.
2. What are the key minerals that constitute felsic and mafic rocks?
The mineral composition is a direct result of their chemical makeup. Felsic and mafic rocks are primarily composed of silicate minerals, but the types differ significantly:
Felsic Rocks: Dominated by light-coloured minerals such as Quartz, Orthoclase Feldspar, and Muscovite Mica.
Mafic Rocks: Dominated by dark-coloured minerals like Olivine, Pyroxene, Amphibole, and Biotite Mica.
3. Can you give some common examples of felsic and mafic rocks?
Certainly. Both types include intrusive (formed underground) and extrusive (formed on the surface) variants:
Examples of Felsic Rocks: Granite (intrusive) is a very common example, often used in construction. Rhyolite (extrusive) is its volcanic equivalent.
Examples of Mafic Rocks: Basalt (extrusive) is the most common rock on Earth's surface, forming the ocean floor. Gabbro (intrusive) is its plutonic equivalent.
4. How do the properties of felsic and mafic magma affect volcanic eruptions?
The properties of the magma determine the style of a volcanic eruption. Felsic magma has a high silica content, making it highly viscous (thick and sticky). This viscosity traps gases, leading to a build-up of pressure that results in explosive, violent eruptions. In contrast, mafic magma has a low silica content and is less viscous (runny). Gases can escape easily, so eruptions are typically effusive, characterised by flowing lava like that seen in Hawaii or at mid-ocean ridges.
5. Why are the rocks called 'felsic' and 'mafic'?
The names are acronyms derived from their typical elemental composition. The term 'felsic' comes from 'fel' for feldspar and 'sic' for silica, the two main components. The term 'mafic' comes from 'ma' for magnesium and 'fic', which relates to ferric or iron. These names directly describe the primary mineral-forming elements within the rocks.
6. In what tectonic settings are felsic and mafic rocks typically formed?
The formation of these rocks is closely linked to plate tectonics. Mafic rocks, like basalt, are primarily formed at divergent plate boundaries (such as mid-ocean ridges) and oceanic hotspots, where magma from the mantle rises directly to the surface. Felsic rocks, like granite, are commonly formed at convergent plate boundaries, where the subduction and melting of oceanic and continental crust create silica-rich magma.
7. How does the cooling rate of magma impact the texture of felsic and mafic rocks?
The cooling rate determines the size of the mineral crystals in the rock. Magma that cools slowly beneath the Earth's surface (intrusive) allows large crystals to form, resulting in a coarse-grained texture called phaneritic (e.g., granite and gabbro). Lava that cools rapidly on the surface (extrusive) allows for only very small crystals to form, leading to a fine-grained texture called aphanitic (e.g., rhyolite and basalt).
