The Earth’s Crust © Lisa Michalek

Earthquakes Any vibrating, shaking, or rapid motion of the Earth’s crust Most occur when stress builds along a zone of weakness or a break in the rock known as a fault When the crust shifts, energy is released The energy radiates in all directions through vibrations

Earthquakes The place underground where the break occurs is the focus of the earthquake The epicenter is the location at the Earth’s surface just above the focus

Measuring Earthquakes Magnitude (Richter Scale) Seismographs are the most reliable measures of earthquakes Each increase in one unit of magnitude means a ten-fold increase in shaking Intensity (Mercalli Scale) Based upon the reports of people who experienced the earthquake and observed the destruction

Mercalli vs. Richter Scale

Seismic Waves P-Waves Primary (they arrive first), Pressure, or Push-Pull Material expands and contracts and particles move back and forth in the path of the wave. Sound waves that travel through solids, liquids or gases.

Seismic Waves S-Waves Secondary (arrive later), Shear, or Side-to-side Material shears out of shape and snaps back Travels only through solids

Seismic Waves Surface Waves Travel along the earth's surface The slowest waves but the ones that damage in large earthquakes

An Earthquake’s Epicenter Seismologists Scientists who study earthquakes Use the difference in the speeds of P and S-Waves from three seismic recording stations to locate the epicenter

Earthquake Origin Time To find the origin time, a seismologist needs to know the arrival and travel time of the P-waves

The Earth’s Layers The Crust Varies from 5-60 KM In most places, a thin layer of sedimentary rocks covers the mostly granite-like rocks of the continental crust The oceanic crust, under layers of marine sediments, is composed of darker and denser rocks similar to basalt

The Earth’s Layers The Mantle Extends to a depth of about 2900 KM Earthquake waves travel faster in the mantle than they do in the crust Composed mostly of dense, the dark mafic minerals olivine and pyroxene

The Earth’s Layers The Core Composed of iron and nickel Outer Core is thought to be liquid because S-waves are unable to pass through the outer core The Inner Core seems to be solid

The Earth’s Layers

Earthquake Shadow Zones When a major earthquake occurs, both P-waves and S-waves are received over most of the earth The opposite side of the earth will receive P-waves but no S-waves S-waves cannot penetrate the liquid outer core There is also a region where neither P-waves or S-waves are received Refraction (bending) of the waves at the mantle-core boundary causes this ring-shaped region known as the shadow zone

Earthquake P-wave Shadow Zones

Earthquake P-wave Shadow Zones A P-wave traveling through the outer core is labeled K A bounce off the core is labeled c A P-wave in the inner core is I S-waves do not pass through the core, because the outer core is fluid

The “Ring of Fire” A large number of the world’s volcanoes and seismic events occur around the edges of the Pacific Ocean Japan, the western coast of the United States are on the Ring of Fire These areas are damaged frequently by earthquakes and volcanoes

Seismic Hazards Earthquakes can cause damage by shaking, movement of the crust, or large waves in oceans, called tsunamis Seismic Risk Level Maps for the U.S. Probability of damage in 100 years Blue = none green = minor yellow = moderate red = major

Volcanic Hazards When volcanoes erupt they may spew hot lava, hot ash, and/or toxic gases The lava and ash can bury cities, and the toxic fumes can suffocate people Volcanoes can also provide fertile soil that is composed of weathered volcanic material

Continental Drift In 1912, Alfred Wegener, proposed that in the distant past, Earth’s continents were all joined as a single landmass He said that the continents have separated and collided as they have moved over Earth’s surface for millions of years

Continental Drift Wegener proposed that if the land areas were brought back together, the move would line up ancient mountain ranges, similar continental rock formations and evidence of ancient glaciers There are even similar fossils on both sides of the Atlantic that would be brought back together by the re-assembly of Pangaea

Continental Drift

Evidence from the Oceans In the 1950’s both fossils and the analysis of radioactive material showed the age of the oceanic crust increases with distance from the mid-ocean ridges Some oceans were growing wider from the middle Scientists also used magnetic measurements of the oceanic crust

Plate Tectonics The surface of Earth is composed of about a dozen major rigid, moving crustal plates and several smaller plates These plates contain areas of light continental rock and dense oceanic bottoms

Plate Boundaries The lines along which plates meet and interact Convergent boundaries occur from converging plates As a result of this collision mountains rise as the crust crumples

Plate Boundaries Subduction occurs when a dense oceanic plate dives beneath a lighter continental plate Subduction forms ocean trenches that are linear fractures and are the deepest parts of the oceans

Plate Boundaries When a plate slides past another plate, they meet at a transform boundary San Andreas Fault in CA

Plate Boundaries A divergent boundary (rift) is found at the mid-ocean ridges where upwelling material creates new crust that moves away from the ridge in both directions

What Moves the Plates? Convection currents within Earth enable heat to escape from the Earth’s interior These currents create and expand the ocean bottoms, and they carry the continents as “rafts” of lighter rock

Hot Spots In several places on earth, hot plumes of magma pierce the crust As a crustal plate moves over this source of magma, volcanoes form at the hot spot This movement of a plate leads to the formation of a chain of volcanoes of differing ages One example is the Hawaiian Islands