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E&S 8

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Question
Answer
Earth's radius   6370 km  
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average depth of ocean   4 km (70%)  
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continent's average elevation   840 m above sea level  
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what are the layer of the earth? (outer to inner)   crust, mantle, outer core, inner core  
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which layer is the only one that is liquid and NOT solid rock?   outer core  
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alfred wegener   noticed continents matched like a puzzle, found fossils on different continents; suggested continental drift theory  
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Sir Harold Jeffreys   objected Wegener's theory and stalled the study of plate tetonics for forty years  
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Emile Argand   used to study medicine then switched to geology; agreed with Wagener; amplified plate tetonics theory and theory of evolution; examined sediment placement  
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Arthur Holmes   proposed that rocks flow because they are heated from below and cooled from above; silly putty example (pull fast  
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how slow do rocks flow?   mantle rocks flow a few cm a year; takes around 100 million years to flow from top to bottom of mantle  
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age of earth   4.6 billion  
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oldest rocks   4.2 billion  
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most forms of life started to appear   around 500 million years ago  
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oldest oceanic seafloor today   200 million years  
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convection   flow driven by heating; heat from below and cool from top; top sinks, bottom rises; liquid continually overturns  
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harry hess   discovered midocean ridges, proposed sea floor spreading  
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earth's magnetic field   switches sign randomly every .5  
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how fast do tetonic plates move?   0 to 20 cm/year; 25 miles per million years  
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number of plates   10  
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pangaea   around 350 to 175 million years ago all continents were connected, NA on equator and dinosaurs ruled to earth  
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supercontinent progression (youngest first)   Gondwanaland, Pangeae, Rodinia, Columbo, Kenorland, Ur, Vaalbara (God, Please Reserve, Can Keep U Virginal)  
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Wilson Cycle   the openning and closing of the ocean floor, seafloor younger than continental crust  
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crust types   ocean: 8km; continents: 30 km, floats on mantle  
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types of plate boundaries   divergent, convergent, transform  
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divergent plates   plates move away from each other, mantle rises to fill the space; midocean ridges, rift in contintental plate  
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convergent plates   plates move toward each other, one gets pushed down while the other gets pushed up, subduction zones  
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transform plates   rub against each other, no land is created or destroyed  
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subduction zones   large and frequent earthquakes, crust is destroyed, earthquakes occur at surface to 700 km below  
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3 types of subduction   ocean to ocean (trenches are deepest in ocean), ocean to continent (active volcanism), continent to continent (makes mountains because it does not subduct  
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faults   can be active or inactive, can be seismic or aseismic  
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trust v normal faults   in thrust, hanging wall move up; in normal, footwall moves up  
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3 exceptions for most quakes occuring at plate boundaries   mid continental quakes, hotspots, blurring at plate boundaries  
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ductile v brittle   ductile is slow, everyday plate movement while brittle is fragil rock with fast motion that can be found around the time of earthquakes  
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earthquake occurance formula   slip in earthquakes=fault rate x time between quakes  
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why you can't count on a formula   little earthquakes take some of the slip, earthquakes trigger others to occur before they are due, calculation most useful as a "warning"  
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stress   force per unit area  
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strain   the fraction of size that a body is destroyed  
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linear elasticity   when stress is proportional to strain  
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friction increases with   depth; pressure grows, more strain accumulated, deep quakes release a lot more stress  
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fault trace   where fault plane intersects the Earth's surface  
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fault scarp   steep slope formed by fault motion, erosion smoves scarps with time, it sticks up like a ledge  
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rupture process   rock breaks and slides against each other, sliding rocks send vibrations outward, most of damage in quakes is caused by vibrations  
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focus   point where the rupture started  
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hypocenter   location and time of start of quake  
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epicenter   surface projection of hypocenter  
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rupture   the breaking of rocks and sliding of one side of the fault against the other side, occurs when stress exceeds strength  
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crack speed after rupture   3 km/sec  
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crack lenghth   larger length means greater magnitude and longer duration  
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magnitude and approximate rupture sizes   Mag 8: 500 km; Mag 7: 70 km; Mag 6: 10 km; Mag 4: 200m; Mag 2: 5m  
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wave   disturbance that travels far through a medium  
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seismic waves   vibrations of the ground, elastic waves  
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raypaths and wavefronts   raypaths are lines that show the direction that the seismic wave is propagating; wavefronts connect positions of the seismic wave that are doing the same thing at the same time; raypaths are generally perpendicular to wavefronts  
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amplitude   the max wave height, high amplitude=high sound  
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wavelength   horizontal length of one cycle of a wave  
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period   the time required for one wavelength  
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frequency   number of waves that pass a certain poin in a given amount of time  
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velocity   rate at which the wave travels; V=wavelength/period=wavelength X frequency  
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3 kinds of elastic waves   longitudinal, horizontal transverse, vertical transverse  
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types of seismic waves   Body waves (P and S), Surface waves (Love and Raleigh)  
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P Waves   longitudinal, material moves back and forth in the direction the wave travels, fastest type of wave, 5  
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S Waves   material moves back and forth perpendicular to wave direction, arrives second to P wave, 3  
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surface waves   travel on surface of earth, slower than S waves, largest amplitude; Love waves go side to side, Raleigh waves go up and down  
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formula to measure distance from EQ   (Difference in time of P and S waves)/[(1/Velocity S) -(1/Velocity P)]  
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complications for seismic waves   reflection, refraction, conversion  
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measuring stress and strain in nature   stress cannot be determined so we look to measure strain (deformation)  
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seisometer   instrument that record the motions in the ground  
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mass spring seismometer   requires one part to be attached to the ground and another to be isolated from the ground, requires a spring to return mass to original position and a damping mechanism to stop mass from moving and affecting future recordings, and also a pivot so mass mov  
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types of seismometers   mass/spring, challenger space study, remote locations  
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magnitude   measures the size of the earthquake  
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intensity   Measures the effect of an earthquake at a location; Scale from 1 to 12; Obtained from damage to buildings, changes in the earth's surface, felt reports; useful for historic earthquakes and comparing today's to past  
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measures of an earthquake   magnitude, intensity, length of fault that breaks, area of fault break, displacement, seismin moment (area X displacement), death or injuries, damage ($)  
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earthquake effects   ground shaking, ground settling, landslide & avalanches, fault offset, tsunamis & seiches  
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human assisted hazards from a quake   fires, flood from dam failure, toxic spills  
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ways of measuring an earthquake   felt reports (not very accurate), seismic measurements, mapping of rupture zone, Geodetic measurements of ground shift, Geologic observations of past earthquakes (fault displacements)  
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magnitude   measure of the earthquake's size; Determined by taking the logarithm of the largest ground motion recorded form a particular wave type, correction for distance from seismometer to epicenter; Several types depending on wave  
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Charles Francis Richter   made Ritcher scale in 1935, nudist, help telephone, no grad student, had seismometer on his coffee table  
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Richter magnitude   M=log(10)A where A is the amplitude on the instrument; Ex: M=log(1mm)=3, M=log(1000mm)=6  
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different types of magnitudes   M(L): local or Richter mag, uses S wave; M(B): body wave magnitude, P wave at 30 to 90 degrees; M(S): surface wave mag; M(W): moment magnitude, uses seismic moment  
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how large can earthquakes get?   in 1960 Chile recorded M(W) 9.5, but we have only been recording for 50 years; the whole earth breaking in half M(W) 12; subduction quakes hit 9; transform and ridge quakes hit 8  
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seismic moment   M(O)=mui*Distance*S(surface area ruptured) N.m  
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moment magnitude   M(W)=2/3log(M(O))-6  
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rule of thumb on magnitudes   a quake X+1 has 10 times greater amplitude, 3.3 times longer length and duration, 33 times greater energy in waves at release time  
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explosions   first motions are all compressive in all directions, this is how you can tell it is different from an earthquake  
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how many earthquakes are there in a year?   15 w/ mag>7, 155 w/ mag>6, 1300 w/ mag>5, 10,000 w/ mag>4, linear relationship, about 20,000 a year w/ mag>1  
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Gutenberg/Richter relationship   equation for # of quakes; Log N=a  
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earthquake regular occurance   a little less than one mag 3 per week, but most can't even be felt  
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seqence   set of quakes that appear related in space and time  
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foreshock   quake followed by a bigger quake, can occur hours before, only half of mainshock have foreshocks, near mainshock hypocenter  
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mainshock   biggest quake in a sequence; larger mainshocks have more aftershocks, foreshocks and aftershocks usually mag or more smaller than mainshock  
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aftershock   quake after the biggest quake in a sequence; Near mainshock rupture zone; Can number in thousands; Can go on for years or decades; Most predictable and studied quakes  
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corollaries   one never knows that a quake is a foreshock until the bigger mainshock coems along; Aftershocks can turn into foreshocks  
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differences between mainshocks and aftershocks   none, they are all earthquakes that just occur at different times in the sequence  
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Omori's Law   number of aftershocks decreases with time, N=C/t; and the likelihood of having big quakes decreases too  
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non conventional sequences   swarms. long range triggering, jumping faults  
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swarms   most common in volcanic areas, no obvious mainshock  
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Alaska   subduction thrust plate boundary, most dangerous faults in US with 8 eq > M=8 in last 100 years; Queen Charlotte fault  
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Diblee Maps   mapped CA on foot, wrote paper proposing lateral displacement along SA fault by 250 km  
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Eastern CA Shear Zone   3 largest earthquakes in 140 years  
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Wasatch   Nevada, Utah, Idaho, Montana, Wyoming; 10  
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Why is an earthquake famous?   remarkable by size, destruction, particular setting; proximity  
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How earthquakes damage trees   beheading, cutting roots  
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December 1812   bad year for missions, two quakes, learned trees could be a good source about quakes when historical info is short, large quakes can cause damage far from fault  
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1971 Sylmar quake   structures are damaged not only by how hard you shake but also by how long, dams subject to liquefaction  
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1994 Northridge quake   buried fault=blind fault  
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1984 Loma Prieta quake   liquefaction dangerous in artificial landfills, shaking amplified by soft soil  
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1946 Alaska quake/tsunami   waves reached HI, Santa Cruz, Chile; in deep water, waves travel as fast as jets (800 km/hr)  
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tsunami   an ocan wave caused by motion of seafloor in quake, volcanic eruption or landslide; bigger wave created in deeper water; slow down in shallow water but have greater height  
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Chile 1960   largest earthquake in the world  
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1995 Kobe, Japan   costliest earthquake in history, compareable magnitude to Northridge but did more damage  
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1556 Shaanix, China earthquake   deadliest quake ever, 0.83 million  
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1975 Haicheng, China   thought they could predict earthquakes, but then 14 months later there was the worst disaster of the 20th century  
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Turkey   like California in that there are strike slip quakes, had a series of quakes in the 1940s  
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2004 Sumatra Andaman earthquake   M9.0, 3rd largest ever, along subduction of IndoAustralian plate under Indonesia and the Berma plate, earth's rotation actually sped up and shortened the day  
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by 2.8 microseconds, no way to get warning to coastline communities   (blank)  
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Human factors that worsened the 2004 Sumatra quake   destruction of coral reefs, coastal mangrove forests and natural sad dunes  
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Lessons learned from earthquakes   (1)large EQ have large rupture area (2)can occur in unexpected places (3)exposed fault not an indicator size (4)EQs interact and sometimes progress along faults (5)people density & building practices determine # deaths (6)2ndary effects can be worse  
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Avoid living on fault   could be used for parks or streets; try to live at least 5 miles from a fault  
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Hazards due to ecological conditions (site)   soft soil increases shaking, wet soil liquefaction or landslides, cliffs and ridges are prone to landslides  
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Soft sites   stronger shaking, seismic waves grow in amplitude when passing from rock to softer material, uneven settlement  
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liquefaction   heavy solid objects (houses) will sink while hollow objects (septic tank) will float  
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cliffs and ridges   experience greater shaking because of wave reflection in concentrated area; landlisde and rockfall potential  
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Three basic considerations in building   (1) materials (2) design (3) quality of execution  
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Types of lateral bracing   diagonal, shear-wall, and frame-action  
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Soft story   openings present on first floor of building that reduce the strength of the wall; garage, doors, windows  
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wood frame with stucco   bad, adds weight and makes buildling weaker, can fall off, 1" of stucco=1/4" plywood  
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Earthquake preparedness   60% chance most people will be at home in the event of a quake  
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common hazzards   furniture, pictures on walls, items falling on beds  
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To make an earthquake prediction, you need to state   (1) time interval it will occur (2) region it will be (3) projected magnitude  
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possible (false) EQ precursors   (1)increase or decrease in # of EQs (2)slow round motion (3)random emission (4)electrical resistivity (4)electromagnetic field (5)water chemistry (6)seismic wave velocity  
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problems with false alarms   expensive, disruptive, make people less likely to respond  
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hazard and risk   hazard is probability that an area will be affected; risk is probability that loss will occur; preparation lowers risk, not hazard; Risk=hazard*vulnerability*value  
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