Volcanos, Lava, and Simulations in Houdini

Volcanoes are the structures that help shape the surface of the earth.

They have helped create 80% of the planet’s surface. The force from a volcano can create mountains, create cracks in the surface of the Earth, lava rivers, and much more. There are volcanoes on every continent in the world. Around 1,500 volcanoes in the world are active, and about 10% of them are in the United States.

They are ruptures in the crust of a planetary object, and because of this, it means they can be located on any planet in the Universe. They generally spew lava, volcanic ash, and other gases stored under the Earth’s crust.

They are mostly found where the Earth’s tectonic plates are diverging or converging. However, a large chunk of them are found underwater. When you hear of the Mid-Atlantic Ridge or The Pacific Ring of Fire, these areas are areas that contain underwater volcanoes. Which again were formed by divergent tectonic plates.

Our planet’s lithosphere is always shifting and bumping into other pieces of itself. When they collide, one of them will plunge under the other into what we call the subduction zone. The temperatures are often extreme in this zone, and when these collision events happen they release magma.

Volcanoes can also form where the crust of the Earth is stretching, or is very thin. Usually, this is caused by wells of volcanic material trying to push itself upwards. These volcanic areas are very isolated to themselves, and are just pockets of lava waiting to be pushed out of a volcano. This is something called hotspot volcanism.

As you might have guessed, volcanoes are involved in plate tectonics. Earth’s lithosphere is considered the most rigid outer shell of our planet. It is currently broken up into 16 larger plates and some smaller ones.

Each volcano has its own unique eruption pattern. Some just burp up lava, while others have very violent eruptions. This all comes down to what chemical reaction is going on in the volcano’s molten core. If the magma of a volcano is less viscous, then the explosion will be considered effusive. An effusive eruption is one that has lava flowing out of it straight away. With the lava out of the way, the volcano is free to release all the gas inside of it.

An explosive eruption is a bit different. This happens when the lava and molten rock traps gases under the volcano. With nowhere to go, these gases build up, and pressure builds under the Earth’s surface. Then the volcano blows up.

75% of the world's volcanoes are located in a region called The Ring of Fire. This zone stretches for over 25,000 miles. It is located between the southern tip of South America, the West Coast of North America, and through the Bering Sea to Japan. As well as through New Zealand.

Volcanoes

Some Facts on Plate Tectonics

There are some interesting theories to plate tectonics so let's cover them.

Each plate boundary generates its own unique geological processes and landforms. At divergent boundaries, the plates of the Earth separate. They can spurt hot water, magma, molten rock, and gases. These elements then solidify into basalt, and form new matter on the earth’s crust.

Divergent Plate Boundaries:

These events are best observed at the bottom of the seafloor. When two plates diverge from each other, hot mantle rock sneaks up in between them. This also leads to the rock around it melting, the creation of new ocean crust, and volcanism. In these divergent areas, black smokers, volcanic islands, and deep sea vents are found.

Convergent Plate Boundaries:

These are the opposites of divergent plate boundaries. This phenomena happens in subduction zones. These are zones where a continental plate and an oceanic plate collide. The oceanic plate subducts, which are forced under the continental plate, then form deep ocean trenches. This process also causes something called flux melting to occur. This releases water from subducting plates and lowers the overall melting points of surrounding plates. However, this also helps the production of magma. This magma is often filled with silica based particles. Chains of volcanoes line these areas in something called volcanic arcs.

Hotspots:

We’ve mentioned hotspots above. So here is a deeper dove into them. These volcanic hotspots are thought to be formed by mantle plumes from the core-mantle area of the Earth. These columns of hot material have nowhere to go but up, and then form volcanoes on top of them. However, as we know tectonic plates move around. Whenever they move on top of one of these magma plumes, the volcano on top of them becomes inactive. Then, when the plate moves away, new volcanoes are created.

Continental Rifting:

When magma and mantle rock is pushed upwards under a plate it becomes trapped. With no gap or crack in the plate to escape from, it starts to increase a build up of pressure until the tectonic plate splits apart. Then a new divergent plate is created.

Underwater Volcanoes

Underwater volcanoes are also known as submarine volcanoes. They are vents of fissures in the Earth’s surface, and look a bit different from what you would consider a traditional volcano. They are located in mid-ocean ridges. (tectonic plate formation areas) They account for about 75% of the magma output of Earth. There is thought to be well over a million undocumented underwater volcanoes currently on the ocean floor.

Most of these volcanoes are located in deep areas of the ocean. However, some of them are located in the shallows. The Kolumbo submarine volcano was one of these. It was only discovered when it erupted in 1650, and forever reshaped the Santorini coastline.

The majority of submarine volcanoes are seamounts. These are extinct volcanoes that rise out of the seafloor. They are around 1,000-4,000 meters high. Their surrounding peaks are often found hundreds of thousands of meters below the surface of the ocean. There are around 30,000 of these seamounts currently in existence around the globe.

One of the world’s largest volcanoes is called Havre. It exists 3,000 meters under the Pacific ocean. For about 90 days in 2012 lava poured out of it and its 14 surrounding vents. It is the largest deep water eruption ever recorded.

The way underwater volcanoes shape the surface of the Earth is very different from the way their counterparts on the surface do. Ones on above water have the luxury of releasing their gases and debris into the atmosphere, and having the pressure inside them released all at once. Ones under the ocean aren’t so lucky. They are under constant amounts of pressure from the surrounding ocean water, and sometimes experience pressure between 92-122 times that of sea level. This constant pressure dampens their explosions and the way their debris is scattered. It also shapes how lava is formed. When lava comes into contact with the water it instantly solidifies, versus in air where it takes time to cool.

Volcano Traits

There are some signature traits that make up most volcanoes on the planet. As well as some unique varieties of them.

Fissure Vents:

These are flat, linear fractures that lava emerges from.


Shield Volcanoes:

These are volcanoes that have very broad shield-like shapes. They are formed from low-viscosity lava, and do not have large dramatic explosions. These volcanoes are mostly found in the ocean, and in areas like Iceland.

Lava Domes:

These are built when highly viscous lava flows away from the volcano. They are sometimes formed in the crater of a previous volcanic eruption, but can also form by themselves. They produce violent, explosive eruptions.

Cryptodomes:

These are formed when viscous lava is forced upwards and causes a bulge in the Earth’s surface.

Cinder Cones:

These are volcanoes that when they erupt, have large amounts of scoria and pyroclastics build up around their vents. Scoria is a type of lightweight black or green volcanic rock with holes in it. Pyroclastics are fast moving solidified lava pieces that are projected away from the explosion. When both of these pieces fall away from the event, they appear to look like cinders.

Based on satellite images scientists have suggested that these types of volcanoes exist on other worlds in our Solar System.