axelsfrida
Continental-continental_convergence_Fig21contcont
This is a diagram of how a stratovolcano is formed.
Where the two plates meet, sometimes one moves down, while the other moves upward. As the plate that is moving down is forced deeper, parts of it begin to melt and form magma that rises to the surface, often in explosive eruptions. The plate that rises, tends to create large, classic, cone-shaped volcanoes called stratovolcanoes, such as Mt. Hekla.
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Explain why the eruption happened>
It is most likely that the eruptio happened because the tetonic plates that meet in Iceland and sometimes split apart with terrific results. Sometimes the plated go in different directions, up and down, but sometimes they move in different direction rubbing against one another. When a plate moves down (subduction), being forced deep, part of it begin to melt and form magma that rises to the surface, often in explosive eruptions. Subduction zones tend to create large, classic, cone-shaped volcanoes called stratovolcanoes, such as Mt. Hekla.
Continental-continental_convergence_Fig21contcont
This is a diagram of how a stratovolcano is formed.
Where the two plates meet, sometimes one moves down, while the other moves upward. As the plate that is moving down is forced deeper, parts of it begin to melt and form magma that rises to the surface, often in explosive eruptions. The plate that rises, tends to create large, classic, cone-shaped volcanoes called stratovolcanoes, such as Mt. Hekla.
===============================================================
Explain why the eruption happened>
It is most likely that the eruptio happened because the tetonic plates that meet in Iceland and sometimes split apart with terrific results. Sometimes the plated go in different directions, up and down, but sometimes they move in different direction rubbing against one another. When a plate moves down (subduction), being forced deep, part of it begin to melt and form magma that rises to the surface, often in explosive eruptions. Subduction zones tend to create large, classic, cone-shaped volcanoes called stratovolcanoes, such as Mt. Hekla.