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1. Seismicity & Earthquakes
2. Questions 1) Where would you expect the higher earthquake insurance rates: Florida or Oregon?
2) Briefly explain.
3) Did you use inductive or deductive reasoning ?
4) explain
3. What is an Earthquake? Vibration of the Earth produced by the rapid release of energy.
Energy release due to plate tectonics and failure (fault zones) of the Earth’s crust
Energy radiates as waves in all directions from the focus (source)
Epicenter – surface expression of the focus
4. Elastic Rebound Theory Tectonic forces slowly deform the rock
As the rock bends, it stores energy
When the rock’s resistance to the stress is overcome, the rock slips or breaks
Slippage occurs at the weakest point (focus), rock “snaps” back to original position
Energy released produces the vibrations we know as an earthquake
6. Earthquake Waves - Seismicity Seismic waves – elastic energy released at the focus following the rupture of rock
Seismology- study of earthquake (seismic) waves
Seismograph – instrument that records earthquake waves
Seismogram – record of the seismic waves
7. Seismogram
8. Seismogram
9. Seismic Waves P-waves and S-waves are body waves, they travel through the Earth’s interior. Surface waves travel along the Earth’s outer layer.
10. P-waves – Primary Waves Compressional wave – push and pull rock in direction of movement
Can travel through all materials (solids, liquids, and gases)
Fastest moving wave
Smallest wave amplitude (lowest energy)
11. S-waves – Secondary Waves Shear wave - Waves shake material at right angles to their direction of movement
TRAVEL ONLY THROUGH SOLIDS
Intermediate speed – 2nd to arrive as seismic station
12. Surface waves Move up and down, similar to ocean waves
Can also move side-to-side.
Very damaging waves
Travel the slowest – last to arrive at seismic station
Greatest wave amplitude (highest energy)
14. Locating Earthquakes Need three seismic stations.
Use the time difference (tH) in the arrival of the p-waves and the s-waves.
Distance (d) extrapolated from a time-distance graph.
A circle with a radius of d is drawn around the seismic station.
Earthquake occurred somewhere on the circle.
The intersection from three stations shows the epicenter location.
15. Locations of Earthquakes By studying 1000s of earthquakes, geologists learned most occur along plate boundaries
16. Earthquake Intensity and Magnitude Mercalli intensity scale
Assesses the damage from an earthquake at a specific location
Based upon human observation
Can vary from location to location
17. Earthquake Intensity and Magnitude Richter Scale
Describes the earthquakes magnitude (energy released)
Measures amplitude of largest wave, adjusted for travel time
Is the same from location to location
A 1 digit increase in Richter scale is a 30 fold increase in energy released
18. Is the Earth Entirely Solid? What piece of the Earth is not solid?
How do we know this?
Seismic waves
Different materials transmit waves at different speeds, i.e. p-waves change speed as they move from the crust to the mantle and from the mantle to outer core
19. Wave Movement Through Homogeneous Earth
20. Movement through material of different density
21. Velocity and Amplitude Are a Function of the Material
22. Velocity Profile Through Earth
23. Liquid causes p-waves to bend (refract)
Refraction of waves creates a zone where no p-waves are recorded (shadow zone)
103 to 143 degrees from focus
P-wave Shadow Zone
24. S-wave Shadow S-waves cannot pass through liquid
Waves refract at surface of outer core, creating a zone where no s-waves are recorded (shadow zone)
103 to 180 degrees from focus
25. Why did the 1895 EQ have a wider radius of influence?
26. Earthquake Prediction
27. Time Interval Analysis Statistics is used to generate a “best-fit line” which can be used to predict the time of the next earthquake
Not reliable
This example has not occurred
28. Seismic Gap Look at the location of earthquakes
Areas (Gaps) where no earthquake has happened is an area of accumulating strain
Gaps represent locations of future earthquakes
29. Seismic Gap Examples Alaska
30. Environmental Impacts Tsunami
Giant tidal waves created by earthquakes
Move at speeds between 500 and 950 km/hr (300 – 600 miles/hr)
Waves reach height of over 30 meters (100ft)
31. Landslides and ground subsidence
Vibrations cause unstable material to slide down slopes
Vibrations cause stable material to turn into fluid – liquefaction