2. What are Earthquakes? The shaking or trembling caused by the sudden release of energy Most commonly found at or near to plate margins Usually associated with faulting or breaking of rocks Continuing adjustment of position results in aftershocks

3. What is an Earthquake? Rock does not move smoothly against rock. –Pressure at plate boundaries builds up –Eventually the pressure is too great and the rock moves –Energy is released in waves that radiate outward from the fault

4. The Focus and Epicenter of an Earthquake The point within Earth where faulting begins is the focus, or hypocenter The point directly above the focus on the surface is the epicenter

5. FOCUS EPICENTRE FAULT LINE SHOCK WAVE

6. Zhang Heng invented the seismoscope, or Di Dong Yi (Earth Motion Instrument) for measuring earthquakes. A similar device did not reach Europe until sixteen hundred years later, when a seismoscope was "invented" again in France. Heng's device was made of bronze in the shape of an urn eight feet in diameter. Although Heng's original seismoscope was destroyed, Wang Zhenduo reconstructed it in 1951. Inside the seismoscope is a copper pendulum shaft connected to eight copper arms. Outside the device are eight dragon heads around the top, each with a ball in its mouth. Around the bottom, eight frogs squat with open mouths, each directly under a dragon head. When an earthquake occurred, a ball fell out of a the dragon's mouth into a frog's mouth, making a noise that was supposedly loud enough to wake the Emperor's household, alerting them of the earthquake.

7. Seismographs record earthquake events At convergent boundaries, focal depth increases along a dipping seismic zone called a Benioff zone

8. The Slinky and The Rope Earthquakes generate several kinds of seismic waves including P, for "Primary" and S, for "Secondary" waves. P Waves The P waves move in a compressional motion similar to the motion of a slinky, while the S waves move in a shear motion perpendicular to the direction the wave is travelling. S Waves

9. Body Waves: P and S waves Body waves –P or primary waves fastest waves travel through solids, liquids, or gases compressional wave, material movement is in the same direction as wave movement –S or secondary waves slower than P waves travel through solids only shear waves - move material perpendicular to wave movement

10. Surface Waves: R and L waves Surface Waves –Travel just below or along the ground’s surface –Slower than body waves; rolling and side-to-side movement –Especially damaging to buildings

11. How is an Earthquake’s Epicenter Located? Seismic wave behavior –P waves arrive first, then S waves, then L and R –Average speeds for all these waves is known –After an earthquake, the difference in arrival times at a seismograph station can be used to calculate the distance from the seismograph to the epicenter.

12. How is an Earthquake’s Epicenter Located? Time-distance graph showing the average travel times for P- and S- waves. The farther away a seismograph is from the focus of an earthquake, the longer the interval between the arrivals of the P- and S- waves

13. How is an Earthquake’s Epicenter Located? Three seismograph stations are needed to locate the epicenter of an earthquake A circle where the radius equals the distance to the epicenter is drawn The intersection of the circles locates the epicenter

14. How are the Size and Strength of an Earthquake Measured? Modified Mercalli Intensity Map –1994 Northridge, CA earthquake, magnitude 6.7 Intensity –subjective measure of the kind of damage done and people’s reactions to it –isoseismal lines identify areas of equal intensity

15. How are the Size and Strength of an Earthquake Measured? Magnitude –Richter scale measures total amount of energy released by an earthquake; independent of intensity –Amplitude of the largest wave produced by an event is corrected for distance and assigned a value on an open-ended logarithmic scale

18. Excellent Guardian Earthquake Site http://www.guardian.co.uk/flash/0,5860,112 1610,00.htmlhttp://www.guardian.co.uk/flash/0,5860,112 1610,00.html

19. Where Do Earthquakes Occur and How Often? ~80% of all earthquakes occur in the circum-Pacific belt –most of these result from convergent margin activity –~15% occur in the Mediterranean-Asiatic belt –remaining 5% occur in the interiors of plates and on spreading ridge centers –more than 150,000 quakes strong enough to be felt are recorded each year

21. Three Types of Faults Strike-Slip Thrust Normal

22. What type of fault? THRUST !!

23. Strike-slip Fault Example

24. 1906 San Francisco Earthquake

25. Normal Fault Example Dixie Valley-Fairview Peaks, Nevada earthquake December 16, 1954

26. Thrust Fault Example

28. The Economics and Societal Impacts of EQs Damage in Oakland, CA, 1989 Building collapse Fire Tsunami Ground failure

30. This event is still WAITING to happen.

31. What are the Destructive Effects of Earthquakes? Ground Shaking –amplitude, duration, and damage increases in poorly consolidated rocks

32. Can Earthquakes be Predicted? Earthquake Prediction Programs –include laboratory and field studies of rocks before, during, and after earthquakes –monitor activity along major faults –produce risk assessments

33. What are the Primary and Secondary Effects of Earthquakes. The primary effects of an earthquake are those things which happen as the ground is shaking. The secondary effects are those things which happen after the ground has stopped shaking as a result of the quake. These may be minutes to years after the event. Which do you think create the most problems, Primary or Secondary effects.

34. Primary Effects - Ground Shaking Northridge, CA 1994

35. Primary Effects - Ground Shaking Northridge, CA 1994

36. Primary Effects - Ground Shaking KGO-TV News ABC-7 Loma Prieta, CA 1989

37. Primary Effects - Ground Shaking Kobe, Japan 1995

38. Primary Effects - Ground Shaking Kobe, Japan 1995

39. Primary Effects - Surface Faulting Landers, CA 1992

40. Primary Effects - Liquefaction Source: National Geophysical Data Center Niigata, Japan 1964

41. Primary Effects - Landslides Turnnagin Heights,Alaska,1964 Source: National Geophysical Data Center

42. Secondary Effects - Fires KGO-TV News ABC-7 Loma Prieta, CA 1989

43. Secondary Effects - Tsunamis Photograph Credit: Henry Helbush. Source: National Geophysical Data Center 1957 Aleutian Tsunami

44. Create a table listing the positive and negative effects of Earthquakes Brainstorm factors which are positive and negative about earthquakes. Fill them in on a table. Positive AffectsNegative Affects Weak Buildings FallHomes/ Buildings destroyed

45. Positive EffectsNegative Effects Weak Buildings Fall, strong buildings survive Homes/ Buildings destroyed or damaged Brings communities togetherPeople die or are injured Improves emergency servicesBridges/roads damaged/blocked Research and prediction improvesLooting, crime, lawlessness Aid from overseas leads to short term improved quality of life Fires from gas leaks Improves building standardsElectricity outages, gas and telephone services disrupted Work in ConstructionWater and Sewage pipes break Controls Population-survivors benefit.Disease Insurance rates increase Industries damaged