Deck 10: Major Geochemical Cycles

A) carbon 14.
B) carbon 13.
C) carbon 12.
D) all isotopes of carbon.

A) istopically heavy to istopically light samples.
B) istopically light to istopically heavy samples.
C) unknown samples to a standard sample to which all others are compared.
D) unknown samples to the average of all samples for the study at hand.

A) melting of methane hydrates.
B) volcanoes that form along subduction zones.
C) metamorphism of limestones.
D) thermal processes along mid-ocean ridges.

A) flux.
B) feedback.
C) respiration.
D) photosynthesis.

A) decomposition; oxygen compounds
B) burial; oxygen compounds
C) burial; reduced carbon compounds
D) decomposition; reduced carbon compounds

A) phosphorus.
B) oxygen.
C) nitrogen.
D) carbon dioxide.

A) carbon dioxide
B) sugars
C) water
D) oxygen

A) Water
B) Sugars
C) Oxygen
D) Carbon dioxide

A) animals; decomposers and plants
B) plants; decomposers and animals
C) decomposers and plants; animals
D) decomposers and animals; plants

A) nitrogen and phosphorus.
B) water and carbon dioxide.
C) silicon and oxygen.
D) iron and magnesium.

A) river channels.
B) deep marine areas.
C) shallow marine settings.
D) swamps.

A) oxygen
B) carbonic acid
C) carbon dioxide
D) sulfur

A) heavier; winter; summer
B) lighter; summer; winter
C) heavier; summer; winter
D) lighter; winter; summer

A) light carbon
B) heavy oxygen
C) light oxygen
D) heavy carbon

A) light; increased burial of carbon dioxide
B) light; increased burial of organic carbon
C) heavy; increased burial of organic carbon
D) heavy; increased burial of carbon dioxide

A) photosynthesis.
B) amino acids.
C) decomposition.
D) burial.

A) terrestrial plants; marine plankton
B) marine plankton; terrestrial plants
C) marine animals; terrestrial plants
D) terrestrial plants; marine animals

A) oxygen 16; energetic
B) oxygen 18; energetic
C) oxygen 16; sluggish
D) oxygen 18; sluggish

A) shrinks; oxygen; carbon dioxide
B) shrinks; carbon dioxide; oxygen
C) enlarges; carbon dioxide; oxygen
D) enlarges; oxygen; carbon dioxide

A) Early Paleozoic.
B) Late Paleozoic.
C) Mesozoic.
D) Cenozoic.

A) marine; calcite; aragonite sea
B) terrestrial; aragonite; aragonite sea
C) marine; calcite; calcite sea
D) terrestrial; aragonite; calcite sea

A) increased solar output during that time.
B) unfortunate errors in how we calculate global temperatures.
C) evolution of many new types of planktonic organisms.
D) expansion of glaciers across large areas of Earth's landmass.

A) small and sea level was high.
B) large and sea level was high.
C) small and sea level was low.
D) large and sea level was low.

A) climate was stable, so climate change is not a factor.
B) methane hydrates were melting.
C) phytoplankton became less productive.
D) bacterial respiration rates remained steady.

A) light oxygen
B) heavy carbon
C) light carbon
D) heavy oxygen

A) "aragonite seas."
B) "calcite seas."
C) an "aragonite sea" and in a "calcite sea," respectively.
D) a "calcite sea" and in an "aragonite sea," respectively.

A) lower solar output of energy during that time.
B) errors in how we calculate global temperatures.
C) the Paleozoic greenhouse working differently than today.
D) expansion of glaciers across large areas of Earth's landmasses.

A) increased global precipitation rates.
B) acceleration of the chemical reactions of weathering.
C) weathering depletes carbon dioxide from the atmosphere.
D) expansion of forest areas.

A) global dry conditions
B) evolutionary expansion of large plants
C) decreased global temperatures
D) widespread mountain-building