Transcript Slide 1
Global seismicity Earthquake epicenters (locations) are shown by the colored dots. Note locations and concentrations of activity. Compare with volcano locations. Plate collisions and volcanoes • Ocean-ocean • Ocean-continent • Continentcontinent India-Asia continent-continent collision Rock Behavior • How rocks respond to applied forces (stress) • Stress – force per unit area (lbs per sq in) • Response is termed “strain” – Elastic deformation (reversible) – Ductile deformation (flow) – Brittle deformation (fracture) Rock breakage • Fracture – Separation only; no vertical movement • Fault – Vertical and/or horizontal motion Note offset in rocks Footwall block Hanging wall block Note different fault motions Normal or dip-slip fault Strike-slip fault Reverse fault Strike-slip motion on the plates Note relative position of features Subduction process Shallow-focus: 0 to 70 km depth Intermediate-focus: 70 to 300 km depth Deep-focus: 300 to about 700 km depth P- and S-wave motion Note changes in amplitude of the three wave arrivals Seismogram of EQ near recording station Selected seismic stations in the US Earthquake magnitudes • Measures the “size” of an EQ • Four types of measurements – Local (ML) – original Richter scale – Body-wave (Mb) – P-wave amplitude – Surface-wave (Ms) – Rayleigh-wave amplitude – Moment (Mw) – considers amount of strain energy release along entire fault rupture. Comparison of magnitude scales The Big Ones Japan Mar 2011 9.0 Intensity scale • Measures damage caused by seismic energy • Established by Mercalli (Italian) in 1902; modified in 1931 to reflect enhanced building standards in US • Uses Roman numerals (I – XII) • Values depend on EQ magnitude, distance from source, bedrock type, building material and style, duration of shaking Isoseismal map of Dec 1811 EQ near New Madrid, MO Earthquakes don’t kill peoplebuildings do • Many deaths in older regions on Earth due to poor quality construction, especially through trans-Mediterranean/Asiatic belt • Secondary events (aftershocks) destroy already weakened structures • Surface waves produce the greatest damage Benefits of EQs • Changing natural resource paths – Groundwater – Oil and natural gas – Exposures of minerals • Natural mitigation – Small events lessen likelihood of large events Short-term predictions • Precursors – Events that imply an EQ; usually small magnitude events, often in swarms – Foreshock (sometimes) – main shock – aftershock • Ground deformation • Water level changes in wells • Seismic gaps – Greatest potential for large events in the gap Sample seismogram showing P, S, and surface waves Effects of EQs • • • • • • Shaking and ground rupture Liquefaction Regional elevation changes Landslides Fires Disease Humans cause earthquakes by • Crustal loading by dams and reservoirs • Injection of liquid waste • Underground nuclear explosions Human caused Eqs near Denver, CO Earthquakes in the United States Where do most EQs occur in US and why? What’s happening in eastern & central US Subduction zones in western North America • Alaska – Subduction of Pacific Plate • Pacific Northwest (BC-WA-OR-CA) – Subduction of Juan de Fuca Plate and smaller Gorda Plate – Cascadia Subduction Zone – Volcanoes on land Subduction Zone Earthquakes • Largest EQs worldwide – 9 of the 10 largest earthquakes (1904-2008) were related to plate subduction • One in Tibet was due to India hitting Asia – These 9 occurred along Circum-Pacific “Ring of Fire” – Five EQs were located in northern Pacific [Japan-Kamchatka-Aleutians] Examples of Subduction Zone Earthquakes • Chile 1960 (Mw = 9.5): Nazca Plate diving under South American Plate; tsunami producer • Alaska 1964 (Mw = 9.2): Pacific Plate dives beneath North American Plate; tsunami producer • Mexico 1985 (Ms = 8.1): Cocos Plate dives beneath North American Plate • Indonesia 2004 (Mw = 9.1): India Plate dives under Burma Plate; major tsunami producer • Japan 2011 (Mw = 9.0): Pacific Plate dives under North American Plate; major tsunami producer Seismic Gap, Mexico, Sept 19,1985 Ms = 8.1 • Mexico earthquake filled Michoacan seismic gap • Guerrero gap remains • Major aftershocks of Ms =7.5 and 7.3 within a month Fig 2.20a Average annual worldwide frequency of EQs magnitude 6.0 or greater • M 6.0 – 6.9 Strong • M 7.0 – 7.9 Major 15-20 • M 8.0+ Great 1 every 2-3 years 100 San Andreas Fault System • Movement occurs on many faults • Displacement is distributed over a wide zone • Right-lateral strike-slip motion San Andreas: Earthquake Probabilities • Probability of major earthquake (1988-2018) • Use historical and sag-pond data to calculate recurrence intervals Loma Prieta, Oct 17,1989 [World Series EQ] • • • • • • Magnitude 6.9; 67 killed Epicenter at Loma Prieta, highest peak in Santa Cruz Mountains 100 km SSE of San Francisco Section of San Andreas that moved in 1906 EQ ruptured again Marina district in SFO was built on rubble from 1906 EQ; mud was pumped in to fill holes; very unstable “land” Game 3 halted by Commissioner; after 10-day recess, series continued in Oakland – Oakland swept series 4 games to 0. Fig 2.18a Seismic Wave Amplification near Oakland Plate boundary is not a discrete line, but rather a zone the width of the Bay Area Notice the many major faults that are parallel to the San Andreas fault Location of Hayward fault Univ of California stadium in Berkeley The trace of the Hayward fault runs through goal posts Left side is moving N [top of image] 30 yrs of activity; crosses are epicenters New Madrid, Missouri, 1811-2 • Series of three earthquakes in Mississippi River valley (Dec 1811-Feb 1812) • 4 main events, 3 w/ magnitudes > 8.0 ! • Knocked down chimneys 400 miles away! • Shook windows 800 miles away! • Neotectonic analysis indicates earlier EQs in 500, 900, 1300, 1600 AD recurrence interval of 200-400 years. • Why did it affect such a large area? EQs associated with volcanoes • Those connected with active subduction such as western U.S. – Much larger magnitudes due to brittle rock • Isolated volcanism such as Hawaii – Usually lower magnitude due to molten rock Foci of Hawaiian EQs