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Published byAnneleen van der Heijden Modified over 6 years ago
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epicenter the place on the earth’s surface just above the center of an earthquake This diagram shows the epicenter of an earthquake.
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Types of Waves Compression wave Transverse Wave Seismic Wave
Body Waves Primary or p-wave Secondary or s-wave Transverse wave Surface Love wave Rayleigh wave
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Seismic Wave Seismic waves are the waves of energy caused by the sudden breaking of rock within the earth or an explosion. They are the energy that travels through the earth and is recorded on seismographs. There are several different kinds of seismic waves, and they all move in different ways. The two main types of waves are body waves and surface waves.
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Body Waves P Waves (compression wave)
The first kind of body wave is the P wave or primary wave. This is the fastest kind of seismic wave. The P wave can move through solid rock and fluids, like water or the liquid layers of the earth. It pushes and pulls the rock it moves through just like sound waves push and pull the air.
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Stop and Think Have you ever heard a big clap of thunder and heard the windows rattle at the same time? The windows rattle because the sound waves were pushing and pulling on the window glass much like P waves push and pull on rock. Sometimes animals can hear the P waves of an earthquake. Usually we only feel the bump and rattle of these waves.
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Body Waves S wave (transverse wave)
The second type of body wave is the S wave or secondary wave, which is the second wave you feel in an earthquake. An S wave is slower than a P wave and can only move through solid rock. This wave moves rock up and down, or side-to-side.
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Surface Waves Love Waves
The first kind of surface wave is called a Love wave, named after A.E.H. Love, a British mathematician who worked out the mathematical model for this kind of wave in It's the fastest surface wave and moves the ground from side-to-side.
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Surface Waves Rayleigh Waves
The other kind of surface wave is the Rayleigh wave, named for John William Strutt, Lord Rayleigh, who mathematically predicted the existence of this kind of wave in A Rayleigh wave rolls along the ground just like a wave rolls across a lake or an ocean. Because it rolls, it moves the ground up and down, and side-to-side in the same direction that the wave is moving. Most of the shaking felt from an earthquake is due to the Rayleigh wave, which can be much larger than the other waves.
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Seismic P (compressional) and S (shear)
wave propagation (both are body waves)
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Seismic Rayleigh and Love wave
propagation (both are surface waves)
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Other Characteristics
Characteristics of Seismic Waves Table 2: Seismic Waves Type (and names) Particle Motion Typical Velocity Other Characteristics P,Compressional, Primary, Longitudinal Alternating compressions (“pushes”) and dilations (“pulls”) which are directed in the same direction as the wave is propagating (along the raypath); and therefore, perpendicular to the wavefront VP ~ 5 – 7 km/s in typical Earth’s crust; >~ 8 km/s in Earth’s mantle and core; 1.5 km/s in water; 0.3 km/s in air P motion travels fastest in materials, so the P-wave is the first-arriving energy on a seismogram. Generally smaller and higher frequency than the S and Surface-waves. P waves in a liquid or gas are pressure waves, including sound waves. S, Shear, Secondary, Transverse Alternating transverse motions (perpendicular to the direction of propagation, and the raypath); commonly polarized such that particle motion is in vertical or horizontal planes VS ~ 3 – 4 km/s in typical Earth’s crust; >~ 4.5 km/s in Earth’s mantle; ~ km/s in (solid) inner core S-waves do not travel through fluids, so do not exist in Earth’s outer core (inferred to be primarily liquid iron) or in air or water or molten rock (magma). S waves travel slower than P waves in a solid and, therefore, arrive after the P wave.
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Characteristics of Seismic Waves
L, Love, Surface waves, Long waves Transverse horizontal motion, perpendicular to the direction of propagation and generally parallel to the Earth’s surface VL ~ km/s in the Earth depending on frequency of the propagating wave Love waves exist because of the Earth’s surface. They are largest at the surface and decrease in amplitude with depth. Love waves are dispersive, that is, the wave velocity is dependent on frequency, with low frequencies normally propagating at higher velocity. Depth of penetration of the Love waves is also dependent on frequency, with lower frequencies penetrating to greater depth. R, Rayleigh, Surface waves, Long waves, Ground roll Motion is both in the direction of propagation and perpendicular (in a vertical plane), and “phased” so that the motion is generally elliptical – either prograde or retrograde VR ~ km/s in the Earth depending on frequency of the propagating wave Rayleigh waves are also dispersive and the amplitudes generally decrease with depth in the Earth. Appearance and particle motion are similar to water waves.
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A simple wave tank experiment – a ping pong ball is dropped onto the surface of the water; small aid viewing of the waves; distance marks on the bottom of the container allow calculation of wave velocity.
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Seismic P (compressional) and S (shear)
wave propagation in the slinky
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Tsunami Evacuation Map
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Possible large-scale earthquakes and tsunamis in Japan
Tokyo Inland EQ Tokai EQ Tonankai & Nankai EQ I could say that we have been successful to some extent to reduce damage mainly from meteorological disasters like typhoons. However, we are not be able to forecast earthquakes and other sudden on-set disasters in most cases so that they could cause severe damage in particular when they hit densely populated areas as we witnessed in the Kobe EQ. It is also fact that there are wide areas spreading in Japan and off the coast with possible large-scale earthquake sources as shown in this map. Japan Trench & Chishima Trench EQs 49
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Japan and its major seacoasts
Chishima Trench Japan Trench Suruga Trough 200 km 400 km 600 km 800 km 1,000 km Nankai Trough Seismic areas for reinforcing and promoting disaster reduction measures related to the Tokai, Tonankai and Nankai Earthquakes District (undesignated) for promoting seismic disaster reduction measures related to earthquakes along the Japan Trench and the Chishima Trench 48
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Sign of Previous Tsunami Height (2)
Inundated level of previous Tsunami 23
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Promoting Basic Knowledge about “TSUNAMI” Disaster
+ Safe Evacuation Route Early Warning = Understanding of Hazardous Areas Appropriate Risk Awaweness of Local Communities Safe Evacuation 16
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Tsunami Evacuation Area Tsunami Evacuation Building
Pictogram on Tsunami Tsunami Hazard Area Tsunami Evacuation Area Tsunami Evacuation Building Safe place/hill for evacuation against Tsunami. Building for evacuation against Tsunami. There is a high possibility to be flooded in this area when earthquake occurs. 21
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Magnitude in Richter Scale Energy Released in Joules Comment
2.0 1.3 x 108 Smallest earthquake detectable by people. 5.0 2.8 x 1012 Energy released by the Hiroshima atomic bomb. 7.6 x 1013 to 1.5 x 1015 About 120 shallow earthquakes of this magnitude occur each year on the Earth. 6.7 7.7 x 1014 Northridge, California earthquake January 17, 1994. 7.0 2.1 x 1015 Major earthquake threshold. 7.4 7.9 x 1015 Turkey earthquake August 17, More than 12,000 people killed. 7.6 1.5 x 1016 Deadliest earthquake in the last 100 years. Tangshan, China, July 28, Approximately 255,000 people perished. 8.3 1.6 x 1017 San Francisco earthquake of April 18, 1906. 9.3 4.3 x 1018 December 26, 2004 Sumatra earthquake. 9.5 8.3 x 1018 Most powerful earthquake recorded in the last 100 years. Southern Chile on May 22, Claimed 3,000 lives.
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