Earthquakes

Earthquakes

10.1 How & Where Earthquakes Occur

Earthquakes The shaking of Earth’s crust caused by the release of energy. • Over 3 million occur every year

Earthquakes The shaking of Earth’s crust caused by the release of energy. • Over 3 million occur every year • Most are too small to notice

Earthquakes The shaking of Earth’s crust caused by the release of energy. • Over 3 million occur every year • Most are too small to notice • Large earthquakes are extremely destructive and dangerous

Causes of Earthquakes Volcanic Eruption

Causes of Earthquakes Volcanic Eruption Collapse of a cavern

Causes of Earthquakes Volcanic Eruption Collapse of a cavern Impact of a meteor

Causes of Earthquakes Volcanic Eruption Collapse of a cavern Impact of a meteor Built up strain along fault lines (most major earthquakes)

Faults • A break in the lithosphere along which movement has occurred

Elastic Rebound Theory • Friction keeps the plates from moving all of the time

Elastic Rebound Theory • Friction keeps the plates from moving all of the time • Creates Strain

Elastic Rebound Theory • Friction keeps the plates from moving all of the time • Creates Strain • Plates begin to change shape

Elastic Rebound Theory • Friction keeps the plates from moving all of the time • Creates Strain • Plates begin to change shape • Eventually strain becomes too great and the plates shift = earthquake

Elastic Rebound Theory • Friction keeps the plates from moving all of the time • Creates Strain • Plates begin to change shape • Eventually strain becomes too great and the plates shift = earthquake • Plates snap into shape but at a new location

Focus • The point at which the first movement occurs during and earthquake • Where rock begins to move or break • Located many kilometers beneath the surface

Epicenter • The point on earth’s surface directly above the focus

Depth of Earthquake Type of plate boundary determines the depth of an earthquake origin • Transform Boundary = very shallow • Divergent Boundary= ~ 30 km down • Subduction Boundary = 700 km down Typically the shallower an earthquake, the more damage to structures it causes

Seismic Waves

Seismic Waves Energy that is released during an Earthquake travels in waves 2 Types • Body Waves: travel below the surface

Seismic Waves Energy that is released during an Earthquake travels in waves 2 Types • Body Waves: travel below the surface • Surface Waves: travel along Earth’s surface

Body Waves “P” Waves = primary or compression waves • Squeeze and stretch rock material • Can travel through any material: solid rock, magma, water, air • Faster • https://www.tjhsst.edu/~jlafever/wanimate/Wave_Properties2.html

Body Waves “S” Waves = secondary or shear wave • Move materials right and left • Can travel through solid materials but not through liquids or gas • Slower

Surface Waves When “P” and “S” waves reach the Earth’s surface, they produce “Surface Waves” Love Waves • Cause materials to move side to side, perpendicular to waves direction of travel

Surface Waves Rayleigh Waves • Slower than love waves • Moves in an elliptical (circular) pattern

10.2 Locating & Measuring Earthquakes

Seismograph • An instrument used to detect and record waves • Are used to locate epicenter and measure the magnitude of Earthquakes • Over 10,000 stations around the world

Seismographs Different waves require 3 different seismographs • Records up and down motion • Records side to side – north and south • Records side to side – east and west

Seismographs Design • Heavy weight with a pen is attached to base • Base is anchored in bedrock • A record sheet (seismogram) is placed on a drum attached to the base • Drum is turned slowly by a clock • Earthquakes cause the drum to move and the pen to make zigzag marks

Interpreting a Seismogram 1st major zigzag is the “P” wave (fastest) 2nd major zigzag is the “S” wave Followed by surface waves

Interpreting a Seismogram As the P and S waves travel through the ground, the slower S wave lag farther and farther behind So, the larger the gap (lag time) between the 2 waves, the further away the epicenter is from the seismograph station

Travel Time Graph • Shows the relationship between P-wave and S-wave arrival times and the distance from the epicenter

Locating the Epicenter • If you have the distance traveled for 3 seismograph stations you can determine the location of the epicenter • Draw circles according to distance traveled • The spot where all 3 circles overlap is the epicenter

Earthquake Magnitude Magnitude = • the amount of energy released in an earthquake Richter Scale increases logarithmically

10.4 Earth’s Interior

Earth’s Interior By studying earthquakes, scientists have learned about the structure of Earth’s interior. How? Observing and understanding the properties of S and P waves

Observations about P and S Waves • Velocities increase when the waves travel through more dense materials, and decrease when they travel through less dense materials. • S waves cannot travel through liquids

Velocity Example • At a depth of 2900 km, P waves slowed down and S waves stop • Suggests that the material is liquid (outer core) • At a depth of 5200 km, P waves velocity increases again • Suggests that this material is solid (inner core)

The Shadow Zone • A wide belt around the side of Earth opposite the focus of the Earthquake • Seismograph stations do not receive a signal if they are in the shadow zone

Why? • P waves pass through the mantle are refracted (bent) into arcs back to the surface • S waves cannot pass through liquid

The Moho • AndrijaMohorovicic – Croatian seismologist observed a change in velocities of S and P waves between the crust and the mantle • Determined that there is a boundary where the denser rock of the mantle meets the less dense rock of the crust • Located about 32 km under continents and 5-10 km under the ocean

The Transition Zone • A region in the middle of the mantle where changes in the P and S wave velocities occur • Separates the upper and lower mantle

10.3 Earthquake Hazards

Ground Shaking and Foundation Failure • Earthquake waves cause the ground to move up and down and side to side • Side to Side motions cause more buildings to collapse

Liquefaction • Severe ground shaking can cause soil under buildings to settle or liquefy

Other Foundation Failures • San Francisco 1989– buildings constructed on landfill collapsed after the area liquefied • Mexico City 1985– buildings constructed on lake sediments collapsed

Aftershocks • Large earthquakes can be followed by a series of smaller ones • Can be as many as 1000 per day • Can cause damage to building and other structures, especially ones already weakened by the ground shaking

Fire • Earthquakes can cause gas lines and water lines to break • San Francisco 1906 earthquake fire destroyed over 3000 homes and burned 11 sq km of the city

Tsunamis • Underwater Earthquakes and landslides can cause huge waves • Tsunamis can travel very quickly over large expanses of water • Scientists try to predict tsunamis by monitoring wave activity

Preventing Earthquake Damage • Earthquake-prone areas have specific building codes • Engineers and scientists are continually trying to develop buildings that can withstand earthquakes

Earthquakes

Earthquakes

Presentation Transcript

EARTHQUAKES!

EARTHQUAKES

Earthquakes

Earthquakes

Earthquakes

EARTHQUAKES

Earthquakes

EARTHQUAKES

Earthquakes

EARTHQUAKES

EARTHQUAKES

Earthquakes

Earthquakes

Earthquakes

Earthquakes

Earthquakes

Earthquakes

Earthquakes

Earthquakes

Earthquakes

EARTHQUAKES

Earthquakes