Deck 8: Telling Time Geologically

A) radiometric dating of meteorites that have struck the Earth.
B) extrapolation from radiometric dating of the oldest rocks found on Earth.
C) radiometric dating of rocks found on the Moon.
D) the proportional amount of lead isotopes on the Earth.

A) rocks are often found in overturned positions.
B) sediments tend to be deposited in horizontal layers.
C) vast areas have been deformed by tectonic activity.
D) lava flows tend to disrupt horizontally deposited sediments.

A) Erosion of the fault surface.
B) Intrusion of sedimentary layers.
C) Deposition of sedimentary layers.
D) Faulting and offsetting of a dike.

A) 1 billion years old.
B) 3 billion years old.
C) 4 billion years old.
D) 2 billion years old.

A) very old rocks to contain fossils of complex organisms, while younger rocks would contain fossils of both simple and complex organisms.
B) simple organisms to be found in sedimentary rocks more often than complex organisms.
C) the success of an organism determines the abundance of its fossils.
D) very old rocks to contain fossils of only simple organisms, while younger rocks would contain fossils of both simple and complex organisms.

A) Basalt.
B) Gneiss.
C) Schist.
D) Granite.

A) 3.77- billion- year- old chert in Australia.
B) 3.96- billion- year- old gneiss of Canada.
C) 3.46- billion- year- old chert in Australia.
D) 670- million- year- old sandstone of Australia.

A) 4.6 billion years.
B) 570 million years.
C) 3.77 billion years.
D) 3.96 billion years.

A) the dike may be either younger or older than the sedimentary strata.
B) the dike is younger than the sedimentary strata.
C) the dike and the sedimentary strata are the same age.
D) the dike is older than the sedimentary strata.

A) superposition
B) cross- cutting relationships
C) inclusions
D) original horizontality

A) volcanic flood basalts.
B) methane emissions from the sea floor.
C) ice ages.
D) meteorite impact.

A) original horizontality
B) uniformitarianism
C) superposition
D) fossils have evolved over time

A) an eroded surface indicating an unconformity.
B) fossilized sea creatures.
C) rocks containing paleosols.
D) sedimentary rocks containing shallow- water ripples.

A) 3.46- billion- year- old sedimentary rocks.
B) paleosols preserved on the unconformity surface.
C) 3.96- billion- year- old gneisses.
D) 3.52- billion- year- old granites and greenstones.

A) 10,000 years ago (Pleistocene- Holocene).
B) 65 million years ago (Cretaceous- Tertiary).
C) 55 million years ago (Paleocene- Eocene).
D) 250 million years ago (Permo- Triassic).

A) age dating.
B) geometric dating.
C) relative dating.
D) absolute dating.

A) The relative age of a landscape can be determined by observing the surface topography.
B) Younger landscapes have a higher number of surface boulders.
C) Soil is composed of completely weathered material and is of little use in this type of dating.
D) Highly weathered rocks emit a dull thud when struck with a rock hammer, while unweathered rocks emit a ringing sound.

A) the time it takes for half of the parent isotopes to decay to daughter isotopes.
B) the time it takes for the ratio of parent to daughter isotopes to be 1:2 (half as many parent isotopes as daughter isotopes).
C) one- half of the total lifespan of a parent isotope.
D) the time it takes for the ratio of parent to daughter isotopes to be 2:1 (twice as many parent isotopes as daughter isotopes).

A) bacteria, because they have existed in widespread geographic areas since life first began.
B) a specific type of trilobite that existed for only a short geologic time in widespread geographic areas.
C) cockroaches, because they have existed in widespread geographic areas almost since the first appearance of insects.
D) a specific type of bryzoa that existed for only a short geologic time in very limited geographic areas.

A) will appear to be younger than it really is.
B) will not be affected.
C) will appear to be older than it really is.
D) can be determined by measuring the quantity of parent material present.

A) Lichen dating is calibrated for an area by observing lichens on surfaces of known ages such as old tombstones.
B) Lichen dating is accomplished by counting the number of lichen colonies growing on the surface of a rock.
C) Lichenometry is useful for dating young glacial deposits, rockfalls, and mudflows.
D) Lichen dating is useful only for surfaces younger than about 9000 years.

A) The direction of the tracks.
B) The shape of the tracks.
C) The number of tracks.
D) The length of the tracks.

A) the ages of similar fossils found in geographically distant rocks.
B) which geographically distant rock units are the same type of rock.
C) which geographically distant rock units were formed under approximately the same environments.
D) which geographically distant rock units are approximately the same age.

A) eon, era, period, epoch.
B) era, eon, epoch, period.
C) epoch, period, eon, era.
D) eon, epoch, period, era.

A) opening of ocean basins.
B) collision of continents.
C) earthquakes.
D) building of mountains.

A) absolute dating.
B) relative dating.
C) age dating.
D) geometric dating.

A) differences in fossil assemblages.
B) differences in sedimentary rock structures.
C) differences in types of rocks.
D) differences in minerals.

A) horizontal sedimentary strata overlying crystalline rocks.
B) tilted sedimentary strata offset by a fault.
C) horizontal sedimentary strata overlying tilted sedimentary strata.
D) horizontal sedimentary strata overlying eroded horizontal sedimentary strata.

A) The sedimentary rock record of most regions represents only 1% to 5% of Earth's existence.
B) Virtually every sequence of sedimentary rock layers contains one or more unconformities.
C) No single place on Earth contains all of the rock strata composing the entire geologic record.
D) Unconformities occur when plate- tectonic forces cause sediments to be deposited at an angle instead of horizontally.

A) The bodies of organisms take in carbon- 14 throughout their lives and after death until they are isolated from the atmosphere by burial.
B) Carbon- 14 dates are determined by measuring the activity of carbon- 14 and comparing to the initial activity.
C) Rocks dated by the carbon- 14 method are generally in the 100- to 70,000- year age range.
D) Cosmic bombardment changes the rate of production of carbon- 14.

A) it cannot be determined whether the rock or the pluton is older.
B) the rock is the same age as the pluton.
C) the rock is younger than the pluton.
D) the rock is older than the pluton.

A) 3.96 billion years ago.
B) 3.77 billion years ago.
C) 570 million years ago.
D) 4.6 billion years ago.

A) Summer sediment layers are dark- colored, while winter sediments are light- colored.
B) Varve layers are examined in cores extracted from the bottom of a lake.
C) Varves are more apparent in lakes that freeze in winter than in those that do not.
D) Varves can be used to date geologic events that had an effect on a lake.

A) Basalt.
B) Sandstone.
C) Limestone.
D) Granite.

A) landslides.
B) droughts.
C) house posts.
D) an ax handle.

A) preservation in frozen permafrost.
B) preservation in underground burrows.
C) preservation in hardened tree sap.
D) preservation in tar pits.

A) Polar regions.
B) Desert regions.
C) Temperate climates.
D) Equatorial regions.

A) the addition of sufficient dissolved mineral and nutrients in the oceans.
B) the development of hospitable climatic belts.
C) a change in the Sun's emission of ultraviolet radiation.
D) the development of a protective atmosphere.

A) Metamorphic rocks.
B) Igneous rocks.
C) Sedimentary rocks.
D) All of the above.

A) weathering rinds of fossil- bearing sandstone concretions.
B) isotopic dates from interbedded layers of volcanic ash.
C) the temperature- time relationships of nearby metamorphic rocks.
D) isotopic dates from nearby igneous intrusions.

A) volcanoes have always erupted lava.
B) Earth has always rotated at the same speed.
C) Earth has always had continents.
D) Earth has always had rivers.