Earthquakes and Seismology in Earth’s Interior

Professor Dave Explains

1 Aug 202211:30

Summary

TLDRThis script delves into the study of Earth's interior layers: the crust, mantle, and core. Geologists use seismic waves to explore these layers without direct access. Seismic waves, generated by earthquakes, are analyzed for their behavior and velocities to understand the composition and physical properties of Earth's interior. The script explains the types of seismic waves, their characteristics, and how they reveal the structure of the Earth, including the Mohorovičić discontinuity and the core-mantle boundary.

Takeaways

🌏 Earth's interior is divided into three main layers: the crust, the mantle, and the core.
🪨 Xenoliths and ophiolites provide rare physical samples from the upper mantle brought to the surface.
🔥 Kimberlite pipes can bring pieces of the mantle to the surface through ultra-deep volcanic eruptions.
📊 Studying C1 chondrite meteorites gives insights into Earth's composition, as they are considered Earth's parent material.
🔊 Seismic waves, studied by seismologists, offer a way to understand Earth's inner layers without direct exploration.
🏗️ Earthquakes, caused by the release of stress along tectonic plate boundaries, generate seismic waves that can be tracked.
🌊 Surface waves, including Love and Rayleigh waves, travel through the crust and can cause significant destruction.
🌀 Body waves, S-waves and P-waves, travel through the Earth's interior and provide information on its composition and state.
🔍 Seismometers measure the seismic waves, helping to create an 'echogram' of Earth's interior.
🌐 The S-wave shadow zone indicates the presence of a liquid outer core, as S-waves cannot travel through liquid.
📉 The Mohorovičić discontinuity (MOHO) marks the boundary between the crust and the denser mantle, with a sudden increase in seismic wave velocities.
🌌 The asthenosphere, a ductile layer of the mantle, allows for the movement of tectonic plates and is the source of earthquakes and volcanic activity.
📈 Seismic velocities increase with depth in the mantle, indicating changes in rock properties and the presence of the transition zone and D'' layer.
🌐 Ultra low velocity zones may represent areas of partial melting in the D'' layer, potentially related to mantle plumes and core convection.

Q & A

What are the three main layers of the Earth's interior?
-The three main layers of the Earth's interior are the crust, the mantle, and the core.
What are xenoliths and how are they related to Earth's layer composition?
-Xenoliths are strange rocks that are brought to the surface from the upper mantle and provide evidence pertaining to the composition of Earth's layers.
What are ophiolites and how do they bring pieces of the upper mantle to the surface?
-Ophiolites are deposits that result from ancient oceanic crust being thrusted upward and overturned during mountain building events, bringing pieces of the upper mantle to the surface.
How do kimberlite pipes contribute to our understanding of the Earth's mantle?
-Kimberlite pipes can bring pieces of the mantle to the surface in ultra-deep seated volcanic eruptions, providing physical samples of Earth's interior.
What role do C1 chondrites play in studying the composition of Earth?
-C1 chondrites, a type of meteorite, can provide insight into the composition of Earth as they are considered Earth's parent material.
How do geologists use seismic waves to study Earth's inner layers without visiting them?
-Geologists study seismic waves, which are vibrations that rumble through the Earth, to understand the physical properties of Earth's inner layers by analyzing how these waves interact with different rock properties.
What are the two main types of surface waves and how do they differ?
-The two main types of surface waves are Love waves and Rayleigh waves. Love waves move side to side, while Rayleigh waves roll along the surface, similar to ocean waves.
What are the differences between P-waves and S-waves?
-P-waves are compressional waves that move parallel to propagation and are faster, while S-waves are shear waves that move perpendicular to propagation and are slower.
How do seismologists use seismometers to study seismic waves?
-Seismologists use seismometers, instruments sensitive to Earth's vibrations, to measure S- and P-waves from earthquakes and other sources to understand the Earth's interior structure.
What is the significance of the S-wave shadow zone in understanding the Earth's core?
-The S-wave shadow zone, an area where S-waves are dissipated at the outer core, indicates that the outer core is in a dense, liquid state and helps in understanding the Earth's core structure.
What is the Mohorovičić discontinuity (MOHO) and its importance?
-The Mohorovičić discontinuity (MOHO) is the boundary between the crust and the denser mantle, marked by a sudden increase in density and seismic velocities, indicating a change in rock composition and properties.
What is the asthenosphere and its role in plate tectonics?
-The asthenosphere is a ductile layer of the mantle where the rock can flow, marking the boundary between brittle and plastic deformation. It is the layer on which tectonic plates move and where earthquakes and volcanic activity typically occur.
What are the characteristics of the D'' layer and its potential implications?
-The D'' layer, at the bottom of the mantle, is characterized by low and variable seismic velocities and is probably heterogeneous in composition. It may represent areas of partial melting due to increased heat flux from the core, potentially influencing convection patterns and core-mantle heat flux.
How do ultra low velocity zones relate to the Earth's core and mantle dynamics?
-Ultra low velocity zones, characterized by extremely low seismic velocities, may represent areas of partial melting in the D'' layer due to heat from the hot, upward convecting outer core. They could potentially initiate large mantle plumes called superplumes.
What is the significance of the core-mantle boundary in understanding Earth's structure?
-The core-mantle boundary is defined by the disappearance of S-waves and a slowing of P-waves due to the outer core being in a liquid state. It marks the transition from the solid mantle to the liquid outer core and is crucial for understanding Earth's dynamics.