1 / 30

Earthquakes

Learn how crustal plates move and interact through earthquakes, the different types of faults, formation of mountains, and the occurrence of seismic waves during earthquakes.

palmerm
Download Presentation

Earthquakes

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Earthquakes 6.E.2.2 Explain how crustal plates move and interact using earthquakes.

  2. An Earthquake is… • The shaking and trembling that results from the movement of rock beneath Earth's surface • The movement of Earth's plates produces strong forces that squeeze or pull the rock in the crust • This is an example of stress, a force that acts on rock to change its volume or shape

  3. Stress • There are three different types of stress that occur on the crust, shearing, tension, and compression • These forces cause some rocks to become fragile and they snap • Some other rocks tend to bend slowly like road tar softened by the suns heat

  4. Faults • A fault is a break in the crust where slabs of crust slip past each other. The rocks on both sides of a fault can move up or down or sideways • When enough stress builds on a rock, the rock shatters, creating faults • Faults usually occur along plate boundaries, where the forces of plate motion compress, pull, or shear the crust too much so the crust smashes

  5. 1. Normal Faults • Tension forces in Earth's crust causes these types of faults • Normal faults are at an angle, so one piece of rock is above the fault, while the other is below the fault • When movement affects along a normal fault, the hanging wall slips downward • Normal faults occur along the Rio Grande rift valley in New Mexico, where two pieces of Earth's crust are diverging

  6. 2. Reverse Faults • Compression forces produce this fault • This fault has the same setup as a normal fault, but reversed, which explains it’s name • Just like the normal fault, one side of the reverse fault is at an angle of the other • This fault produced part of the Appalachian Mountains in the eastern United States

  7. 3. Strike-Slip Faults • Shearing creates this fault • In this fault, rocks on both sides of the fault slide past each other with a little up and down motion • When a strike-slip fault forms the boundary between two plates, it becomes a transform boundary

  8. How Do Mountains Form? • The forces of plate movement can build up Earth's surface, so over millions of years, movement of faults can change a perfectly flat plain into a gigantic mountain range • Sometimes, a normal fault uplifts a block of rock, so a fault-block mountain forms • When a piece of rock between two normal faults slips down, a valley is created

  9. Mountains Formed by Folding • Sometimes, under current conditions, plate movement causes the crust to fold • Folds are bends in rock that form when compression shortens and thickens part of Earth's crust • The crashing of two plates can cause folding and compression of crust • These plate collisions can produce earthquakes because rock folding can fracture and lead to faults

  10. Anticlines and Synclines • Geologists use the terms syncline and anticline to describe downward and upward folds in rock • An anticline is a fold in a rock that arcs upward • A syncline is a fold in a rock that arcs downward • These folds in rocks are found on many parts of the earths surface where compression forces have folded the crust

  11. Plateaus • Theforces that elevate mountains can also raise plateaus, a large area of flat land elevated high above sea level • Some form when a vertical fault pushes up a large flat piece of rock • Like a lasagna, a plateau consists of many layers, so it is wider than it is tall

  12. How Earthquakes Form • Everyday, about 8,000 earthquakes hit Earth, but most of them are too little to feel • Earthquakes will always begin in a rock beneath the surface • A lot of earthquakes begin in the lithosphere within 100 km of Earth's surface • The focus triggers an earthquake • Focus: the point beneath Earth's surface where rock that is under stress breaks

  13. Seismic Waves Seismic Waves: vibrations that travel through Earth carrying the energy released during an earthquake an earthquake produces vibrations called wavesthat carry energy while they travel out through solid material During an earthquake, seismic waves go out in all directions to the focus They ripple like when you through a stone into a lake or pond

  14. Seismic Waves (Continued) • There are three different types of seismic waves: P waves, S waves, and surface waves • An earthquake sends out two of those waves, P and S waves • When they reach the top of the epicenter, surface waves form

  15. Primary Waves • Also known as P Waves • The first waves to come are these waves • P waves are earthquake waves that compress and expand the ground like an accordion • P waves cause buildings to expand and contract

  16. Secondary Waves • Also known as S Waves • After P waves, S waves come • S waves are earthquake waves that vibrate from one side to the other as well as down and up • They shake the ground back and forth • When S waves reach the surface, they shake buildings violently • Unlike P waves, which travel through both liquids and solids, S waves cannot move through any liquids

  17. Surface Waves • When S waves and P waves reach the top, some of them are turned into surface waves • Surface waves move slower than P waves and S waves, but they can produce violent ground movements • Some of them make the ground roll like ocean waves • Other surface waves move buildings from side to side

  18. Detecting Seismic Waves • Geologists use instruments called seismographs to measure the vibrations of seismic waves • Seismographs records the ground movements caused by seismic waves as they move through the Earth

  19. Mechanical Seismographs • Until just recently, scientists have used a mechanical seismograph • a mechanical seismograph consists of a heavy weight connected to a frame by a wire or spring • When the drum is not moving, the pen draws a straight line on paper wrapped around the drum • Seismic waves cause the drum to vibrate during an earthquake • the pen stays in place and records the drum's vibrations • The higher the jagged lines, the more severe earthquake

  20. Measuring Earthquakes • There are many things to know about the measures of an earthquake • There are at least 20 different types of measures • 3 of them are the Mercalli scale, Richter scale, and the Moment Magnitude scale • Magnitude is a measurement of earthquake strength based on seismic waves and movement along faults

  21. The Mercalli Scale • Developed in the twentieth century to rate earthquakes according to their intensity • The intensity of an earthquake is the strength of ground motion in a given place • Is not a precise measurement • But, the 12 steps explain the damage given to people, land surface, and buildings • The same earthquake could have different Mercalli ratings because of the different amount of damage in different spots • The Mercalli scale uses Roman numerals to rank earthquakes by how much damage they cause

  22. The Richter Scale • The Richter scale is a rating of the size of seismic waves as measured by a particular type of mechanical seismograph • Developed in the 1930’s • All over the world, geologists used this for about 50 years • Electric seismographs eventually replaced the mechanical ones used in this scale • Provides accurate measurements for small, nearby earthquakes • Does not work for big, far ones

  23. The Moment Magnitude Scale • Geologists use this scale today • It’s a rating system that estimates the total energy released by an earthquake • Can be used for any kind of earthquakes, near or far • Some news reports may mention the Richter scale, but the magnitude number they quote is almost always the moment magnitude for that earthquake

  24. Locating the Epicenter • Sine the P waves travel faster than the S waves, scientists can use the difference in arrival times to see how far away the earthquake occurred. • It does not tell the direction however.

  25. Determining Direction • One station can only learn how far away the quake occurred. • They would draw a circle at that radius. • If three stations combine their data, the quake occurred where the three circles overlap.

  26. How Earthquakes Cause Damage • The severe shaking provided by seismic waves can damage or destroy buildings and bridges, topple utility poles, and damage gas and water mains • With their side to side, up and down movement, S waves can damage or destroy buildings, bridges, and fracture gas mains.

  27. Questions What is a break or crack in the Earth’s crust? A. Hole B. Well C. Geyser D. Fault

  28. What is a fold in a rock that arcs upward? A. Syncline B. Anticline C. Seismic wave D. Rock on

  29. What are vibrations that travel through Earth? A. N Waves B. Z Waves C. Seismic Waves D. Supersonic Waves

  30. The End! Earthquakes make me shake!!!

More Related