Volcanology

🌋Volcanology Unit 10 – Volcanoes and Plate Tectonics

Volcanoes and plate tectonics are closely linked, shaping Earth's surface and driving geological processes. This unit explores how tectonic plate movements create conditions for volcanic activity, influencing magma composition, eruption styles, and associated hazards. Understanding these concepts is crucial for predicting and mitigating volcanic risks. We'll examine various volcano types, eruption mechanisms, and monitoring techniques used to forecast volcanic activity and protect communities living near active volcanoes.

Key Concepts and Terminology

  • Volcanology studies the formation, eruption, and hazards associated with volcanoes
  • Plate tectonics describes the large-scale motion of Earth's lithosphere, which is divided into rigid plates that move relative to each other
  • Magma refers to molten rock beneath Earth's surface, while lava is magma that reaches the surface during a volcanic eruption
  • Volcanic edifice is the structure built by the accumulation of erupted material around the vent (stratovolcano, shield volcano, cinder cone)
  • Pyroclastic flows are high-speed, ground-hugging avalanches of hot ash, pumice, rock fragments, and volcanic gas
    • Can travel at speeds up to 700 km/h and reach temperatures of 1,000°C
  • Lahar is a destructive mudflow or debris flow composed of volcanic ash and water from a volcano
  • Tephra includes all solid volcanic material ejected into the atmosphere during an eruption (ash, cinders, pumice)
  • Viscosity measures a fluid's resistance to flow, with high-viscosity magmas being more explosive than low-viscosity magmas

Plate Tectonic Theory Basics

  • Earth's lithosphere is broken into several large plates that move and interact with each other
  • Plates are composed of the crust and the uppermost mantle, known as the lithosphere
  • Plate motion is driven by convection currents in the mantle, with hot material rising and cooler material sinking
  • Plates move at rates ranging from 1-10 cm per year, with the fastest rates occurring at mid-ocean ridges
  • Interactions between plates occur at plate boundaries, which can be convergent, divergent, or transform
  • Earthquakes and volcanic activity are concentrated along plate boundaries
  • The theory of plate tectonics unifies concepts of continental drift, seafloor spreading, and convection in the mantle
  • Hotspots are areas of persistent volcanism not associated with plate boundaries, believed to be caused by mantle plumes (Hawaii, Yellowstone)

Types of Plate Boundaries

  • Divergent boundaries occur where two plates move away from each other, often resulting in the formation of new oceanic crust (mid-ocean ridges)
    • Characterized by shallow earthquakes, basaltic volcanism, and rift valleys
  • Convergent boundaries occur where two plates collide, resulting in subduction, mountain building, and volcanism
    • Oceanic-continental convergence leads to subduction of the denser oceanic plate beneath the continental plate (Andes, Cascade Range)
    • Oceanic-oceanic convergence results in the subduction of one plate beneath the other, forming island arcs and deep-sea trenches (Mariana Islands)
    • Continental-continental convergence leads to the formation of large mountain ranges (Himalayas)
  • Transform boundaries occur where two plates slide past each other horizontally, often resulting in significant earthquakes (San Andreas Fault)
  • Plate boundary types influence the style of volcanism and the composition of magmas produced
  • Divergent boundaries typically produce basaltic magmas, while convergent boundaries can produce a range of magma compositions from basaltic to rhyolitic
  • Intraplate volcanism, such as hotspots, occurs within a plate rather than at a plate boundary

Volcano Formation and Structure

  • Volcanoes form when magma rises through the crust and erupts onto the surface
  • The structure of a volcano depends on the composition of the magma, the eruption style, and the environment in which it forms
  • Stratovolcanoes are steep-sided, conical volcanoes composed of alternating layers of lava flows, volcanic ash, and cinders (Mount Fuji, Mount St. Helens)
    • Typically associated with subduction zones and have a wide range of magma compositions
  • Shield volcanoes are broad, gently sloping volcanoes built from multiple layers of fluid lava flows (Mauna Loa, Olympus Mons)
    • Typically associated with hotspots or mid-ocean ridges and have basaltic magma compositions
  • Cinder cones are small, steep-sided volcanoes built from ejected lava fragments called cinders or scoria (Parícutin, Mexico)
  • Calderas are large, circular depressions formed by the collapse of a volcano's summit or the emptying of its magma chamber (Yellowstone, Crater Lake)
  • Volcanic vents are openings at the Earth's surface through which volcanic materials (lava, tephra, and gases) are erupted
  • Magma chambers are large reservoirs of molten rock beneath the surface that feed volcanic eruptions

Magma Composition and Properties

  • Magma composition refers to the chemical makeup of the molten rock, which influences its properties and eruption style
  • The three main types of magma are basaltic, andesitic, and rhyolitic, which differ in their silica content, viscosity, and gas content
  • Basaltic magma has low silica content (45-52%), low viscosity, and low gas content, resulting in fluid lava flows and effusive eruptions (Kilauea, Hawaii)
  • Andesitic magma has intermediate silica content (52-63%), moderate viscosity, and moderate gas content, often associated with stratovolcanoes and explosive eruptions (Mount Merapi, Indonesia)
  • Rhyolitic magma has high silica content (>63%), high viscosity, and high gas content, leading to highly explosive eruptions and the formation of thick, viscous lava flows or domes (Yellowstone, USA)
  • Magma viscosity increases with increasing silica content and decreasing temperature, affecting the ease with which magma can flow and degas
  • Gas content and composition (primarily water vapor, carbon dioxide, and sulfur dioxide) influence the explosivity of an eruption
  • Magma differentiation processes, such as fractional crystallization and assimilation, can change the composition of magma over time

Eruption Styles and Hazards

  • Volcanic eruptions can be broadly classified as effusive or explosive, depending on the magma composition, viscosity, and gas content
  • Effusive eruptions involve the relatively gentle outpouring of fluid lava, typically associated with basaltic magmas (Kilauea, Hawaii)
    • Hazards include lava flows, which can destroy infrastructure and vegetation, and lava fountains, which can eject molten material hundreds of meters into the air
  • Explosive eruptions involve the violent fragmentation of magma and the ejection of tephra into the atmosphere, typically associated with andesitic to rhyolitic magmas (Mount Pinatubo, Philippines)
    • Hazards include pyroclastic flows, lahars, volcanic ash, and volcanic bombs
  • Pyroclastic flows are high-speed, ground-hugging avalanches of hot ash, pumice, rock fragments, and volcanic gas that can travel hundreds of kilometers from the volcano
  • Lahars are destructive mudflows or debris flows composed of volcanic ash, rock, and water from a volcano, often triggered by heavy rainfall or the melting of snow and ice
  • Volcanic ash is fine-grained material ejected into the atmosphere during an explosive eruption, which can cause respiratory issues, damage infrastructure, and disrupt air travel
  • Volcanic gases, such as sulfur dioxide and carbon dioxide, can pose health risks and contribute to climate change
  • Secondary hazards, such as volcanic earthquakes and tsunamis, can also occur as a result of volcanic activity

Monitoring and Prediction Methods

  • Volcanic monitoring involves the use of various techniques to detect changes in a volcano's behavior that may indicate an impending eruption
  • Seismic monitoring uses seismometers to detect and locate earthquakes associated with magma movement and volcanic activity
    • Increased seismicity, particularly in the form of volcanic tremor, can signal the rise of magma towards the surface
  • Ground deformation monitoring uses GPS, tiltmeters, and satellite imagery (InSAR) to measure changes in the shape of a volcano, which can indicate magma intrusion or chamber inflation
  • Gas monitoring involves measuring the composition and emission rates of volcanic gases, such as sulfur dioxide and carbon dioxide, which can provide insights into the depth and volume of magma
  • Thermal monitoring uses infrared cameras and satellite imagery to detect changes in heat flux, which can indicate the presence of magma near the surface
  • Hydrological monitoring involves tracking changes in nearby water sources, such as springs, streams, and wells, which can be influenced by volcanic activity
  • Geologic mapping and stratigraphic analysis provide insights into a volcano's eruptive history and can help identify patterns and recurrence intervals
  • Eruption forecasting combines monitoring data with statistical models and expert judgment to estimate the likelihood and timing of future eruptions
    • However, precise predictions of eruption timing, duration, and magnitude remain challenging due to the complex nature of volcanic systems

Real-World Case Studies

  • Mount St. Helens, USA (1980): A catastrophic explosive eruption that caused the largest landslide in recorded history and resulted in 57 deaths
    • Demonstrated the importance of volcanic monitoring and hazard assessment
  • Eyjafjallajökull, Iceland (2010): An explosive eruption that produced an ash cloud that disrupted air travel across Europe for several weeks
    • Highlighted the far-reaching impacts of volcanic ash on modern society
  • Kilauea, Hawaii (2018): An effusive eruption that caused significant damage to infrastructure and homes due to the slow-moving but persistent lava flows
    • Showcased the challenges of managing long-duration volcanic crises in populated areas
  • Mount Pinatubo, Philippines (1991): The second-largest volcanic eruption of the 20th century, which produced massive pyroclastic flows and ash fall
    • Successful evacuation of thousands of people due to timely warnings based on monitoring data
  • Nevado del Ruiz, Colombia (1985): An explosive eruption that triggered destructive lahars, resulting in the deaths of over 23,000 people in the town of Armero
    • Emphasized the need for effective risk communication and emergency preparedness in volcanic regions
  • Yellowstone Caldera, USA (last eruption 640,000 years ago): A supervolcano with the potential for a catastrophic eruption in the future
    • Ongoing monitoring efforts aim to detect signs of renewed activity and assess the likelihood of future eruptions
  • Taal Volcano, Philippines (2020): A phreatomagmatic eruption that generated a volcanic lightning storm and forced the evacuation of thousands of people
    • Demonstrated the complex interplay between magma, water, and the atmosphere in certain volcanic systems


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© 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.