Deck 4: Earthquakes

A) Large to small earthquakes that come after a large earthquake.
B) Unlikely to cause damage.
C) Predictable from the primary earthquake's characteristics.
D) Of short duration and occur within a period of a few hours after the major earthquake.

A) The basic design of the structure.
B) The length of the main shock.
C) The material on which the structure is built.
D) All of the choices are correct.

A) Seismometer.
B) Seismogram.
C) Seismograph.
D) Seismocolumn.

A) Are shear waves that move more slowly than P-waves.
B) Are first to arrive at seismic monitoring stations.
C) Are more destructive than surface waves.
D) Both b and c are correct.

A) Richter scale
B) Mercalli scale
C) Moment magnitude scale
D) All the choices are correct.

A) Flooding of coastal areas due to tectonic subsidence.
B) A quicksand-like condition arising in some wet soils during earthquakes.
C) Flooding caused by tsunamis.
D) Flooding caused by dam failure resulting from an earthquake.

A) Ground failure.
B) Ground displacement.
C) Ground motion.
D) Ground damage.

A) Stress.
B) Creep.
C) Rebound.
D) Focus.

A) P waves.
B) S waves.
C) Surface waves.
D) Intensity waves.

A) Are sometimes called "tidal waves" but have nothing to do with tides.
B) Travel very slowly and dissipate a few kilometers from their point of origin.
C) Cross the open ocean as huge breakers, sweeping ships aside.
D) All of the choices are correct.

A) Brittle lithosphere is carried to deeper depths in subduction zones.
B) Subduction zones represent particularly homogeneous regions of the earth's crust.
C) The mantle is less dense under subduction zones.
D) Seismic energy propagates toward the center of the earth under subduction zones.

A) In subduction zones.
B) Along transform faults, such as the San Andreas fault in California.
C) At spreading ridges.
D) Within the interior of plates.

A) Is used along with the maximum amplitude of S waves to determine earthquake magnitude.
B) Is used along with the maximum amplitude of P waves to determine maximum earthquake intensity.
C) Is used to determine how far away the seismograph recorder is from the focus of the earthquake.
D) Both a and c are correct.

A) Dip-slip fault.
B) Normal fault.
C) Reverse fault.
D) Strike-slip fault.

A) There is no predefined upper limit to the Richter scale.
B) On worldwide average, the largest earthquakes, with Richter magnitudes over 8, occur only once every few years.
C) While great earthquakes are rare, there may be hundreds of thousands of small earthquakes each year.
D) There are many more small earthquakes than large ones and the small ones thus account for most of the seismic energy released by earthquakes each year.

A) Get underneath something strong, such as a doorway or heavy table.
B) Run outdoors.
C) Do nothing that will create sparks (do not use light switches, turn on motors of any kind, scrape metal against metal).
D) Attempt to extinguish any open flame (candles, gas stoves).

A) Choose living quarters that will withstand likely seismic waves generated during earthquakes typical of the region.
B) Keep emergency supplies handy and fresh.
C) Know where gas and electric shut-off devices are in the home or apartment.
D) Place tall, heavy furniture next to a bed that is not secured to a wall.

A) The point of first break along the fault.
B) The line along which the fault moved.
C) The point on the earth's surface directly above the focus.
D) The point on the far side of the earth, directly opposite the earthquake.

A) Is the same thing as the epicenter.
B) Can be located using only one seismograph.
C) The primary point of rupture in the earth's crust and origin of the earthquake.
D) None of these choices is correct.

A) It is undergoing rapid creep at this time.
B) It is subject to frequent severe earthquakes.
C) It is a large transform fault.
D) It was the site of the largest earthquakes ever reported in the contiguous United States.

A) Tsunamis.
B) Sand boils.
C) Surface waves.
D) Fault scarps.

A) P waves.
B) S waves.
C) Surface waves.
D) Seismic sea waves.

A) Cushion the shock of the next earthquake.
B) Cause the rocks to swell and close the fault.
C) Reduce resistance to shear along the fault, allowing creep to occur.
D) Reduce the risk of fire from an earthquake.

A) Has been undergoing creep since the 1906 earthquake.
B) Is not of much concern because it is seismically quiet.
C) Is locked and therefore accumulating stress.
D) Is not very dangerous because it only slips a few meters at a time.

A) Many lives have been saved by successful earthquake prediction.
B) Residents of fault zones have gradually been moved to safer areas.
C) All citizens of earthquake-hazard areas have been made thoroughly aware of the risks they face.
D) No great earthquakes have been predicted; its effectiveness is not well tested.

A) Frequency of occurrence of past earthquakes only.
B) Severity of past earthquakes and anticipated ground motion in future ones.
C) A prediction of the likelihood of future earthquakes.
D) Observations of precursor phenomena.

A) Along the San Andreas fault in 1906.
B) In Anchorage, Alaska, in 1964.
C) Near New Madrid, Missouri, in 1811-1812.
D) Near New York City in 1850.

A) A given fault segment accumulates about the same amount of strain energy before rupture each time.
B) The interval between successive earthquakes increases over time on each fault segment.
C) The rate of radon accumulation is also constant, leading to periodic rupture from gas pressure.
D) Major earthquakes occur on large fault zones every 30 years.

A) Ground failure
B) Tsunami
C) Liquefaction
D) Fire

A) Is estimated to have increased; that segment remains locked.
B) Has been eliminated because all the built-up stress has been released.
C) Has been reduced as a consequence of active earthquake-prevention measures now being undertaken.
D) Is no longer a fear, because the Loma Prieta quake confirmed the reliability of earthquake-prediction techniques.

A) Haisheng, China (1975)
B) New Madrid, Missouri (1990)
C) Parkfield, California (1993)
D) Kobe, Japan (1995)

A) Creep.
B) Liquefaction.
C) Tsunamis.
D) A seismic gap.

A) Faults.
B) Folds.
C) Divergence.
D) Subduction.

A) Building strong structures across fault zones to stop fault movement.
B) Establishing a tsunami early warning system.
C) Improving underground drainage in areas with wet soil.
D) Avoiding building on steep slopes near fault zones.

A) Changes in the ground's surface tilt.
B) Changes in frequency of seismic sea waves.
C) Changes in electrical resistivity of rocks.
D) Changes in radon content of well waters.