Deck 7: Earthquakes and the Earths Structure

The San Andreas Fault represents a ______________ fault because the rocks on opposite sides move horizontally.

____________________ are compressional waves and can travel through gases, liquids, and solids.

The deflection of S-waves in what specific part of the Earth's interior proved that the outer core is liquid and causes the Earth's magnetic field to form?

If rock exceeds the limit beyond which it cannot deform elastically, what will happen to the rock? _____________

____________________ ____________________ are elastic waves that travel through rock and are produced by earthquakes.

Earthquakes are motion or trembling of Earth caused by the abrupt release of ____________ stored in rock?

The boundary between the crust and the mantle is known as the ____________________ and the speed of P and S waves increase in this region indicating that a composition change occurs inside the Earth.

Earthquakes are detected and measured with a device called a(n) ____________________.

Most movement of crustal rock occurs due to slippage along established ____________________.

The initial rupture point of an earthquake, where abrupt movement occurs, is the ____________________ and its distance from the Earth's surface influences the potential damage the earthquake will cause.

A seismologist would expect less damage to occur from ____________ waves rather than surface waves because these waves travel through rock and carry some energy to the Earth's surface.

A seismologist would expect more damage to occur from _____________ waves rather than body waves because these seismic waves shake and bounce structures at the surface.

If you were in an earthquake where the ground rolled up and down, what specific type of surface wave did you experience?

Most earthquakes occur along ____________________ boundaries.

As a seismologist, you would have expected the Tohoku earthquake to have a shorter rupture in the fault zone as compared to the Sumatra-Andaman earthquake.

A seismologist would predict that a tsunami produced by an undersea earthquake could travel at 750 kilometers per hour and grow in substantial height as the wave approaches shoreline where friction slows the wave speed down.

Where two tectonic plates move past one another, rock near the plate boundary can stretch or compress elastically for decades, and then fracture suddenly and create an earthquake.

Geologists use a travel-time curve to calculate the distance between the earthquake epicenter and the earthquake focus.

Seismologists rely on foreshocks as an indicator of when a large earthquake will occur because foreshocks precede all earthquakes and ample seismograph data has been collected on foreshocks.

Slippage at the New Madrid fault zone caused the 1906 San Francisco earthquake because the fault zones are connected allowing for fracturing to occur.

An area with granite bedrock would be highly prone to liquefaction during a major earthquake.

Seismologists have found evidence that all of the 30 strongest earthquakes recorded since 1900 have occurred at transform plate boundaries where the impact of colliding plates causes fracturing and faulting of rocks.

In order to determine the epicenter of an earthquake, you would need a minimum of 3 seismograph station seismograms to determine the arrival time of both P and S waves.

If a geologist found evidence of tsunami deposits, submergence of coastal forests from ground displacement, fault rupture, results from computer models and historic documents about an ancient earthquake that occurred in 1700, this would be sufficient data to determine an earthquake occurred at that time.

The monitoring of the electrical conductivity of rock near fault zones is used in long-term predictions of earthquakes and seismologists rely upon this data to help determine where microscopic cracks develop in the rock.

If a large earthquake with a shallow focus occurred in a region like Haiti that has loose sediments and limited bedrock, the man-made structures created with brick and mortar and concrete that is not reinforced would be a high risk for building failure.

P and S waves travel more slowly in the Moho than they do in the crust or below the asthenosphere because the composition changes from basalt to peridotite which is a more dense rock material which slows the speed of the body waves down.

If you were examining Richter Scale readings from earthquakes at mid-oceanic ridges, you would expect their focus to be deeper and stronger than earthquakes that form at convergent plate.

Long-term predictions of when earthquakes will occur are fairly accurate because seismologists have ample seismograph data that indicate specific increments of time between large earthquakes.

Explain how earthquake mortality is linked to the economic status of a region.

Discuss how the structural damage in an earthquake relates to the magnitude, geology, and urbanized areas.

Explain why shallow earthquakes occur at mid-oceanic ridges and deeper earthquakes occur at subduction zones.

Discuss which type of surface wave causes more damage to human structures and the surface.

Explain what best practices that engineers employee to reduce the potential for structural failure in regions with sand sediment and soil during an earthquake.

Explain why the core has a much higher density as compared to the crust and mantle.

Discuss which type of seismic wave causes more damage to human structures and the surface.

Explain why long-term prediction of earthquakes is more accurate than short-term prediction.

Explain why shallow focus earthquakes at subduction zones cause more damage than deeper focus earthquakes.

Explain why seismologists use a travel-time curve to calculate the distance between an earthquake epicenter and a seismograph station.

Explain how scientists have determined the composition and structure of the mantle.

Explain how a big earthquake on the Richter scale could cause limited damage on the Earth's surface.

Explain why the Sumatra-Andaman earthquake lasted for up to 10 minutes.

Explain how plate boundaries from the Precambrian Eon have impacted the New Madrid fault zone today.

Describe how liquefaction occurs in an earthquake.

Explain why moment magnitude is preferred by most seismologists to calculate the energy released in an earthquake as compared to Richter scale.

Explain why seismic waves speed up at discontinuities such as the Moho and slow back down in the mantle.

Explain why the Mexico City earthquake of 1985 destroyed much of that city but caused very little damage in Acapulco which was closer to the epicenter.

Explain how the estimated 9.0 moment magnitude rating of the 1700 Cascadia earthquake was determined.

Explain why many of the world's strongest earthquakes occur in subduction zones.