Deck 17: Life on Earth Qa: Evolution

A) 1,000
B) 3,000
C) 4,000
D) 6,000
E) 9,000

A) 100,000
B) 75,000
C) 50,000
D) 25,000
E) 0

A) carbon-14
B) uranium-238, rubidium-87, and/or potassium-40
C) phosphorus-40, uranium-234, and/or rubidium-87
D) carbon-14 and uranium-238
E) uranium-240

A) thorium-232.
B) lead-232.
C) radon-222.
D) radon-224.
E) lead-206.

A) sedimentary rock.
B) a trace fossil.
C) an insect in amber.
D) a fossil imprint.
E) All of the above.

A) radon-222
B) uranium-234
C) thorium-234
D) lead-206
E) polonium-210

A) carbon-14
B) potassium-40
C) rubidium-87
D) uranium-238
E) lead-206

A) half of the age of a rock's life.
B) the age of a rock's life that is at least 50% likely to be correct.
C) the former size of a rock.
D) the time it takes for half of a rock's isotope atoms to decay.
E) the weight of the isotope in a rock.

A) a pair of identical molecules.
B) two molecules with the same tonicity.
C) an element with an unstable nucleus that decays to a more stable form.
D) an element that generates electrons.

A) the black hole hypothesis.
B) the derivation hypothesis.
C) the extraterrestrial hypothesis.
D) the nebular hypothesis.
E) the solar hypothesis.

A) 1-2 million years old
B) 3-4 million years old
C) 1-2 billion years old
D) 4-5 billion years old
E) 1-2 trillion years old

A) protons.
B) neutrons.
C) electrons.
D) electrons and protons.
E) protons and neutrons.

A) carbon-16.
B) nitrogen-14.
C) carbon-11.
D) boron-12.
E) oxygen-15.

A) peat
B) wood
C) charcoal
D) sedimentary rocks
E) igneous rocks

A) rubidium-87
B) lead-214
C) uranium-238
D) carbon-14
E) potassium-40

A) 12
B) 57,000
C) 5730
D) 1 billion
E) 4.5 billion

A) carbon-14
B) uranium-238
C) uranium-238 and carbon-14
D) carbon-12
E) uranium-240

A) carbon-12
B) uranium-238
C) lead-206
D) carbon-14
E) thorium-234

A) 6,000-8,000 years old.
B) 4,000-6,000 years old.
C) 4,600,000 years old.
D) 4,600,000,000 years old.
E) 4,600,000,000,000 years old.

A) igneous rock
B) sedimentary rock
C) amber
D) in frozen ice packs
E) in deserts

A) at the top
B) at the bottom
C) in the middle
D) in the mid-center
E) in the mid-bottom

A) 1.12 billion years old
B) 2.25 billion years old
C) 4.45 billion years old
D) 6.75 billion years old
E) 8.90 billion years old

A) 5
B) 4
C) 3
D) 2
E) 1

A) around 2.25 billion years and 4.5 billion years, respectively
B) around 9 billion years and 4.5 billion years, respectively
C) around 1.3 billion years and 2.4 billion years, respectively
D) around 4.5 billion years and 9 billion years, respectively
E) The question cannot be answered with the information provided.

A) hydrogen
B) oxygen
C) methane
D) ammonia
E) carbon dioxide

A) Pre-Cambrian
B) Cambrian
C) Paleozoic
D) Cenozoic
E) Mesozoic

A) rubidium-strontium
B) uranium-lead
C) potassium-argon
D) carbon-nitrogen
E) uranium-nitrogen

A) 2 g
B) 0.5 g
C) 1 g
D) 2.5 g
E) 0.25 g

A) rubidium-87
B) lead-214
C) uranium-238
D) carbon-14
E) potassium-40

A) 5
B) 4
C) 3
D) 2
E) 1

A) 13.5
B) 9
C) 1
D) 6.75
E) 11.25

A) Tertiary
B) Quaternary
C) Cambrian
D) Carboniferous
E) Cenozoic

A) Cambrian
B) Archean
C) Jurassic
D) Cretaceous
E) Tertiary

A) Cambrian
B) Jurassic
C) Cretaceous
D) Carboniferous
E) Tertiary

A) ammonia was abundant.
B) hydrogen was abundant.
C) methane was abundant.
D) oxygen was nearly absent.
E) the very first organisms that could survive the early atmosphere were photosynthetic organisms.

A) plants.
B) insects.
C) fish.
D) amphibians.
E) reptiles.

A) Cambrian
B) Tertiary
C) Jurassic
D) Triassic
E) Archean

A) Cambrian
B) Triassic
C) Jurassic
D) Proterozoic
E) Tertiary

A) carbon dioxide, hydrogen, methane, and ammonia.
B) carbon dioxide, methane, and ammonia.
C) hydrogen, methane, and ammonia.
D) oxygen, hydrogen, methane, and ammonia.
E) oxygen, methane, and ammonia.

A) 30-40 million years old
B) 400-500 million years old
C) 800-900 million years old
D) 1-2 billion years old
E) 3-4 billion years old

A) Cenozoic
B) Mesozoic
C) Paleozoic
D) Cambrian
E) Pre-Cambrian

A) invertebrates→algae→amphibians→birds→reptiles→mammals
B) invertebrates→algae→vertebrates→reptiles→amphibians→mammals
C) algae→invertebrates→vertebrates→reptiles→amphibians→mammals
D) algae→vertebrates→ amphibians→reptiles→mammals→invertebrates
E) algae→invertebrates→vertebrates→amphibians→reptiles→mammals

A) Cambrian
B) Archean
C) Jurassic
D) Proterozoic
E) Tertiary

A) evolution has involved several mass extinctions followed by periods of diversification.
B) the first diversification of animal life occurred during the Cenozoic era.
C) when life colonizes new habitats, it rapidly diversifies into new species.
D) the dinosaurs most likely went extinct when a huge asteroid crashed into Earth.
E) oxygen only became abundant in the atmosphere as a result of the evolution of photosynthetic organisms.

A) 10%
B) 80%
C) 75%
D) 95%
E) 99%

A) the planet had a lot of oxygen in the atmosphere and was much warmer.
B) the planet had a lot of oxygen in the atmosphere and was much cooler.
C) the planet had a lot of methane in the atmosphere and was much warmer.
D) the planet had a lot of methane in the atmosphere and was much cooler.
E) the planet had very little oxygen in the atmosphere and was much cooler.

A) vertebrate ancestors, seedless plants on land, amphibians, reptiles
B) vertebrates, insects, seedless plants, reptiles
C) vertebrate ancestors, insects, fungi, reptiles
D) fungi, primitive insects, reptiles, amphibians
E) None of the above.

A) Cambrian explosion.
B) Ordovician explosion.
C) Silurian explosion.
D) Devonian explosion.
E) Carboniferous explosion.

A) 65,000 years ago
B) 650,000 years ago
C) 6.5 million years ago
D) 65 million years ago
E) 650 million years ago

A) volcanism.
B) pangaea.
C) plate tectonics.
D) biogeography.
E) the continental divide.

A) Rhodinia.
B) Pangaea.
C) Laurasia.
D) Gondwana.
E) Pannotia.

A) Their common adaptations are due to the similarities in their environments, but they evolved on separate continents and have always been isolated from one another.
B) Their common adaptations are due to the fact that they both evolved in Africa and later spread to North America. Bison outcompeted wildebeest in North America, though, and wildebeest outcompeted bison in Africa, leaving them separated from one another.
C) Their common adaptations are due to the fact that they are closely related evolutionarily. They live in different areas because wildebeest are extinct in North America.
D) Each species evolved on a separate continent, where the arid grasslands in which they lived forced each species to evolve the same adaptations.
E) None of the above.

A) Pangaea; plate tectonics
B) Gaia; plate tectonics
C) Pangaea; continental tectonics
D) Gaia; continental tectonics
E) Pangaea; geotectonics

A) Cambrian
B) Tertiary
C) Cretaceous
D) Carboniferous
E) Jurassic

A) local climate.
B) distribution of organisms.
C) evolution of species on land.
D) evolution of species near land.
E) All of the above.

A) The distribution of species is determined by the current habitat and climate.
B) The distribution of species is determined by the habitat and climate that prevailed millions of years ago.
C) The distribution of species is determined by where species occurred when Earth's landmasses moved and separated from each other.
D) The distribution of species is determined by ancient and modern barriers to dispersal.
E) All of the above.

A) Oceania.
B) Australasia.
C) Zoolandia.
D) Pangaea.
E) Caladonia.

A) the geographic location of a species.
B) the distribution or range of a species.
C) the adaptations of a species over time.
D) the evolutionary history of a species.
E) All of the above.

A) continental divide.
B) plate tectonics.
C) desertification.
D) continental realignment.
E) continental shift.