3.4 Classification of Igneous Rocks

As has already been described, igneous rocks are classified into four categories, based on either their chemistry or their mineral composition: felsic, intermediate, mafic, and ultramafic. The diagram in Figure 3.16 can be used to help classify igneous rocks by their mineral composition. An important feature to note on this diagram is the red line separating the non-ferromagnesian silicates in the lower left (K-feldspar, quartz, and plagioclase feldspar) from the ferromagnesian silicates in the upper right (biotite, amphibole, pyroxene, and olivine). In classifying intrusive igneous rocks, the first thing to consider is the percentage of ferromagnesian silicates. That’s relatively easy in most igneous rocks because the ferromagnesian minerals are clearly darker than the others. At the same time, it’s quite difficult to estimate the proportions of minerals in a rock.

Based on the position of the red line in Figure 3.16, it is evident that felsic rocks can have about 1% to 20% ferromagnesian silicates (the red line intersects the left side of the felsic zone 1% of the distance from the top of the diagram, and it intersects the right side of the felsic zone 20% of the distance from the top). Intermediate rocks have between 20% and 50% ferromagnesian silicates, and mafic rocks have 50% to 100% ferromagnesian silicates. To be more specific, felsic rocks typically have biotite and/or amphibole; intermediate rocks have amphibole and, in some cases, pyroxene; and mafic rocks have pyroxene and, in some cases, olivine.

Figure 3.16 A simplified classification diagram for igneous rocks based on their mineral compositions [SE]
Figure 3.16 A simplified classification diagram for igneous rocks based on their mineral compositions [SE]

If we focus on the non-ferromagnesian silicates, it is evident that felsic rocks can have from 0% to 35% K-feldspar, from 25% to 35% quartz (the vertical thickness of the quartz field varies from 25% to 35%), and from 25% to 50% plagioclase (and that plagioclase will be sodium-rich, or albitic). Intermediate rocks can have up to 25% quartz and 50% to 75% plagioclase. Mafic rocks only have plagioclase (up to 50%), and that plagioclase will be calcium-rich, or anorthitic.

Exercises

Exercise 3.5 Mineral proportions in igneous rocks

The dashed black lines in the diagram represent four igneous rocks. Complete the table by estimating the mineral proportions of the four rocks (to the nearest 10%).
exercise-3-5

Hint: Rocks b and d are the easiest; start with those.

exercise-3-5-table

Figure 3.17 provides a diagrammatic representation of the proportions of dark minerals in light-coloured rocks. You can use that when trying to estimate the ferromagnesian mineral content of actual rocks, and you can get some practice doing that by completing Exercise 3.6.

Figure 3.17 A guide to estimating the proportions of dark minerals in light-coloured rocks
Figure 3.17 A guide to estimating the proportions of dark minerals in light-coloured rocks

Exercises

Exercise 3.6 Proportions of Ferromagnesian Silicates

The four igneous rocks shown below have differing proportions of ferromagnesian silicates. Estimate those proportions using the diagrams in Figure 3.17, and then use Figure 3.16 to determine the likely rock name for each one.

1a 2a 3a 4a
___% ___% ___% ___%
__________ __________ __________  __________

Igneous rocks are also classified according to their textures. The textures of volcanic rocks will be discussed in Chapter 4, so here we’ll only look at the different textures of intrusive igneous rocks. Almost all intrusive igneous rocks have crystals that are large enough to see with the naked eye, and we use the term phaneritic (from the Greek word phaneros meaning visible) to describe that. Typically that means they are larger than about 0.5 mm — the thickness of a strong line made with a ballpoint pen. (If the crystals are too small to distinguish, which is typical of most volcanic rocks, we use the term aphanitic.) The intrusive rocks shown in Figure 3.13 are all phaneritic, as are those shown in Exercise 3.6. 

In general, the size of crystals is proportional to the rate of cooling. The longer it takes for a body of magma to cool, the larger the crystals will be. It is not uncommon to see an intrusive igneous rock with crystals up to a centimetre long. In some situations, especially toward the end of the cooling stage, the magma can become water rich. The presence of liquid water (still liquid at high temperatures because it is under pressure) promotes the relatively easy movement of ions, and this allows crystals to grow large, sometimes to several centimetres (Figure 3.18). As already described, if an igneous rock goes through a two-stage cooling process, its texture will be porphyritic (Figure 3.15).

Figure 3.18 A pegmatite with mica, quartz, and tourmaline (black) from the White Elephant mine, South Dakota [from http://en.wikipedia.org/wiki/Pegmatite#mediaviewer/File:We-pegmatite.jpg]
Figure 3.18 A pegmatite with mica, quartz, and tourmaline (black) from the White Elephant mine, South Dakota [from http://en.wikipedia.org/wiki/Pegmatite#mediaviewer/File:We-pegmatite.jpg]

License

Icon for the Creative Commons Attribution 4.0 International License

Physical Geology Copyright © 2015 by Steven Earle is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

Share This Book