Time to learn about lava. There are main different types of lava, so let’s break them down.

Lava is molten rock that has been expelled from the center of a planet. Magma is generated by the internal heat of the planet, and it usually melted to a boiling 800-1,200 degrees celsius. The rocks resulting from the cooling of this molten rock are also referred to as lava.

Most lavas contain crystals of minerals, exotic rocks, and previously solidified lava. Because of these crystals , they are given very unique shear and thinning properties. They are not considered Non Newtonian fluids. Instead they are considered Bingham fluids. Bingham fluids are fluids that show resistance until they reach a certain stress threshold. This stress is called yield stress.

A lava flow is an outpouring of lava from an eruption from a planetary surface. Lava can be up to 100,000 times more viscous than water, but it can also flow great distances rapidly and before it cools. Lava that is exposed to air develops a solid crust around it. This crust insulates the lava that is still in its liquid form.

Lava flow speeds are based on viscosity and slope. They typically have a speed of 0.25 mph (0.40km/h). The scaling relationship of lavas regarding velocity is a square of its thickness and divided by its viscosity.

The word lava comes from the latin word labes. Which means to fall or to slide. The first account of the word being used for describing lava was in 1737, during the eruption of Mount Vesuvius.

There are many different types of lava:

Silicate Lavas:

Silicate lavas are molten lava mixtures made up of oxygen and silicon. They are the Earth’s most abundant elements. It is also made up of smaller quantities of aluminium. Calcium, magnesium, iron, sodium, and potassium. The physical properties of this lava type are dictated by its chemical composition. Silicon ions in lava bind extremely well to oxygen ions. Depending on how many silicon and oxygen ions bind together, and in which combination, it can polymerize the lava. The more polymerized the lava is, the more viscous it will become.
Because silica plays such a huge role in determining the viscosity of lava, it’s temperature, and other properties, silicate lavas are divided into four separate groups. These groups are: felsic, intermediate, mafic, and ultramafic.

Felsic Lava:

Felsic lava is a type of lava with a silica content higher than 63%. This category also includes rhyolite and dacite lavas. These lavas are extremely viscous, and are also extremely hot. Their temperature ranges around 1,200-800 degrees celsius. It usually erupts explosively from volcanoes, and produces very fragmental deposits. Rhyolite lava flows usually form lava spines and domes.

Intermediate Lava:

These are lava flows that contain 52%-63% of silica. They contain less aluminium than other types of lava, and they are also richer in magnesium and iron than others. They form on steep composite volcanoes, such as ones in the Andes. They are also hotter than other types of flows. Their temperatures range from 850-1,100 degrees celsius. Its viscosity is around the same as peanut butter. Peanut Butter Lava...Woooooooo!

Mafic lava:

This type of lava has a silica content around 52%-45%, and is also known as basaltic lava. They have an extremely high ferromagnesian content. (iron and magnesium) They erupt at temperatures around 1,100-1,200 degrees celsius. Their viscosities are low, and they flow about the same way as ketchup. This lava type helps form shield volcanoes, and flood basalts. Underwater, they form something called pillow lava.

Ultramafic lava:

These lavas are high in magnesium. They also help form the mineral boninite. They have extremely violent eruptions. They have a silica content under 45%, and contain up to 18% magnesium oxide. Their temperatures sit around 16,000 degrees celsius. They do not polymerize, and are very fast moving. Their viscosity is the same as motor oil.

Alkaline Lavas:

These lavas contain a high amount of alkali metal oxides. (Mainly sodium and potassium) They are mostly found in regions of continental rifting, deeply subducted plates, or in hotspots. They are generated very deep in the Earth’s mantle.