5 Must Know Facts For Your Next Test

1. Viscosity is greatly affected by temperature; as magma cools, its viscosity increases, making it less fluid.
2. The composition of magma plays a crucial role in its viscosity; basaltic magma is less viscous than rhyolitic magma.
3. High-viscosity magma tends to trap gases, increasing pressure until a violent eruption occurs.
4. Different types of volcanoes are associated with varying viscosities of magma; shield volcanoes typically have low-viscosity basaltic magma.
5. Eruption styles range from effusive to explosive, largely depending on the viscosity of the magma involved.

Review Questions

• How does the composition of magma influence its viscosity and subsequent volcanic activity?
  • The composition of magma significantly impacts its viscosity due to variations in silica content. Magma with high silica content, such as rhyolitic magma, has a higher viscosity, making it thicker and less able to flow. This can lead to more explosive volcanic eruptions as gas becomes trapped within the viscous material. In contrast, low-silica magma, like basaltic magma, has lower viscosity and allows for smoother flow and effusive eruptions.
• Evaluate the relationship between viscosity and eruption styles across different types of volcanoes.
  • Viscosity is directly linked to the eruption styles observed in different types of volcanoes. Shield volcanoes, characterized by their broad and gentle slopes, typically erupt low-viscosity basaltic lava that flows easily and creates less explosive eruptions. Conversely, stratovolcanoes often have high-viscosity magma that leads to explosive eruptions due to gas buildup. Understanding this relationship helps predict potential volcanic hazards based on the type of volcano and its associated magma properties.
• Synthesize information on how temperature variations can alter magma viscosity and impact volcanic behavior during an eruption.
  • Temperature plays a crucial role in determining the viscosity of magma, influencing both its flow characteristics and eruption behavior. As temperature increases, viscosity decreases, allowing for more fluid movement of magma within a volcano. Conversely, cooling increases viscosity, leading to potential gas buildup and pressure that can culminate in explosive eruptions. This interplay highlights the importance of monitoring temperature changes in volcanic systems to better understand and predict eruptive activity.

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.