Deck 54: Ecosystems

A) standing crop biomass
B) biogeochemical cycle
C) net primary productivity
D) efficiency
E) gross primary productivity

A) consumers; inorganic material
B) producers; inorganic material
C) carnivores; prey
D) producers; biomass
E) consumers; biomass

A) at the north pole
B) at the south pole
C) between 30^oand 60^o
D) in the Northern hemisphere
E) at the equator

A) less than 1%
B) 1-2%
C) 5%
D) 10%
E) 20%

A) availability of water
B) availability of sunlight and nutrients only
C) depth of the water only
D) depth of the water and availability of sunlight and nutrients
E) availability of oxygen

A) sewage
B) detergent
C) coliform bacteria
D) phosphorous
E) dead fish

A) carnivores and decomposers
B) decomposers and detritivores
C) decomposers and producers
D) herbivores and carnivores
E) producers and herbivores

A) 1 and 2
B) 2 and 5
C) 5 and 20
D) 10 and 50
E) 50 and 75

A) quickly
B) slowly
C) on living material
D) only on organic matter
E) on solar energy

A) 9 kcal per square meter
B) 19 kcal per square meter
C) 190 kcal per square meter
D) 19 kcal per square kilometer
E) 190 kcal per square kilometer

A) mayflies
B) oligochaete worms
C) phytoplankton
D) salmon
E) zebra mussels

A) open ocean
B) extreme desert, rock, sand, ice
C) desert and thornwoods
D) tropical deciduous forest
E) temperate rainforest

A) grazer food webs
B) detrital food webs
C) nutrient cycling
D) species richness
E) inputs of solar energy

A) one
B) two
C) three
D) four
E) five

A) the constant recycling of nutrients between biotic and abiotic components of ecosystems
B) pathways by which energy and nutrients move through biotic components of ecosystems
C) all available nutrients in an ecosystem
D) a series of mathematical equations that define an ecosystem's most important relationships
E) the input of solar energy into a closed ecosystem

A) moving carbon, but not oxygen, from the available organic compartment to the available inorganic component
B) moving oxygen, but not carbon, from the available organic compartment to the available inorganic component
C) moving both carbon and oxygen from the available organic compartment to the available inorganic component
D) moving both carbon and oxygen from the available inorganic compartment to the available organic component
E) moving carbon, but not oxygen, from the available inorganic compartment to the available organic component

A) extracted resources without replacement
B) caused global warming
C) used the water without replacement
D) disrupted energy flow and the cycling of nutrients
E) extracted energy without replacement

A) does not take into effect interactions between organisms
B) does not take into effect nutrient availability
C) does not take into effect water availability
D) may not be accurate
E) may predict disastrous consequences

A) available inorganic compartment; unavailable inorganic compartment
B) unavailable inorganic compartment; unavailable organic compartment
C) available inorganic compartment; available organic compartment
D) available inorganic compartment; unavailable organic compartment
E) available organic compartment; unavailable inorganic compartment

A) They are both typical of most ecosystems.
B) They both indicate that producers are quickly eaten by herbivores.
C) The pyramid for Silver Springs is typical of most ecosystems, and the English Channel pyramid indicates that producers are quickly eaten by herbivores.
D) The pyramid for Silver Springs indicates that producers are quickly eaten by herbivores, and the English Channel pyramid is typical of most ecosystems.
E) Both pyramids indicate overgrowth of producers.

A) assimilation and harvesting efficiencies, and nutrient volume
B) assimilation and harvesting efficiencies, and water volume
C) production, harvesting, and assimilation efficiencies
D) production and harvesting efficiencies, and amount of sunlight
E) production and harvesting efficiencies, and percentage of decomposers

A) energy content of food consumed to the energy content of food available
B) energy absorbed from consumed food to the food's total energy content
C) energy content of new tissue produced to the energy assimilated from food
D) net productivity at one trophic level to the trophic level below
E) producers to consumers

A) the increase in toxicity of a chemical compound resulting from its metabolism by a living organism
B) the higher relative proportion of biomass among producers as compared to consumers in an ecosystem
C) the concentration of nondegradable poisons within organisms at higher trophic levels
D) the concentration of degradable poisons within organisms at lower trophic levels
E) the declining relative proportion of nondegradable poisons in organisms at higher trophic levels as compared to those at lower trophic levels

A) digest
B) grow
C) move
D) reproduce
E) stay warm

A) narrow; narrow
B) narrow; wide
C) wide; narrow
D) wide; wide
E) flat; flat

A) zooplankton
B) small herbivorous fish
C) large predatory fish
D) osprey
E) large herbivorous fish

A) Energy decreases as it passes through each trophic level.
B) Energy increases as it passes through each trophic level.
C) Individual producers are small and very numerous.
D) Herbivorous insects vastly outnumber large producers.
E) Large producers vastly outnumber insects.

A) bacteria
B) biomass
C) nutrients
D) plants
E) the sun

A) primary producer
B) secondary producer
C) photosynthesizer
D) detritivore
E) limiting nutrient

A) continental shelf
B) estuaries
C) kelp beds and reefs
D) open ocean
E) upwelling zones

A) least variable; strongest
B) least variable; weakest
C) more variable; strongest
D) more variable; weakest
E) least variable; constant

A) ecological efficiency
B) harvesting efficiency
C) production efficiency
D) assimilation efficiency
E) net primary productivity

A) We digest and assimilate plant material more efficiently than meat.
B) We digest and assimilate meat more efficiently than plant material.
C) Many regions exist that support vegetation suitable only for feeding large herbivores.
D) Energy efficiency is greater when passed through fewer trophic levels.
E) No biological reaction is 100% efficient.

A) energy flows are difficult to measure
B) most of the sun's energy is harvested
C) only a little energy is transferred from one trophic level to the next
D) the energy flow in carnivores is equal to that of producers
E) trophic energy losses are not significant

A) resemble the pyramid of energy
B) invert
C) widen at the base
D) add trophic levels
E) to become obsolete

A) open ocean
B) savanna
C) swamp and march
D) temperate deciduous forests
E) tundra

A) amount of sunlight absorbed by the plants
B) amount of water accumulated per acre of crop plants
C) total dry weight of plants at a given time
D) number of plant species present
E) productivity of the plants

A) temperature and total number of organisms
B) photosynthesis and availability of nutrients
C) temperature and availability of water
D) photosynthesis and availability of water
E) temperature and photosynthesis

A) indirectly by the abundance of snails
B) indirectly by the abundance of snail predators
C) directly by the abundance of snail predators
D) directly by the availability of nutrients in the salt marsh
E) indirectly by the amount of sunlight penetrating the water

A) ammonification
B) biological magnification
C) denitrification
D) nitrification
E) nitrogen fixation

A) energy
B) matter
C) oxygen
D) photosynthesis
E) ecosystems

A) ammonification only
B) nitrification only
C) nitrogen fixation only
D) ammonification and nitrification only
E) ammonification, nitrification, and nitrogen fixation

A) Earth's crust
B) fertilizer
C) guano
D) legumes
E) water

A) deforestation increases nutrients in nearby aquatic ecosystems
B) deforestation can result in polluted streams
C) deforestation results in calcium retention in soil
D) primary consumers are the most important part of that energy pyramid
E) trees absorb too much water and are not useful in a watershed area

A) atmosphere
B) biomass on land
C) lakes
D) oceans
E) soil

A) refer to the carbon cycle
B) refer to all nutrient cycles
C) originate with human activities
D) refer to absorption of the sun's energy in the atmosphere
E) are caused by human overpopulation

A) bottom-up control
B) top-down control
C) indirect control
D) inverted cascades
E) nutrient cycling

A) oceans
B) polar ice and glaciers
C) rocks
D) lakes and rivers
E) atmosphere

A) consumers
B) nutrients in soil
C) producers
D) sedimentary rock
E) water

A) precipitation; evaporation and transpiration
B) precipitation and evaporation; transpiration
C) precipitation and transpiration; evaporation
D) transpiration; precipitation and evaporation
E) transpiration and evaporation; precipitation

A) carbon dioxide, water, nitrogen, and hydrogen
B) carbon dioxide, water, methane, ozone, and nitrous oxide
C) carbon dioxide, phosphorous, water, and ozone
D) carbon dioxide, methane, and carbon monoxide
E) carbon dioxide, ozone, nitrous oxide, and phosphorous

A) ammonification
B) biological magnification
C) denitrification
D) nitrification
E) nitrogen fixation

A) emit heat energy
B) absorb heat energy
C) emit carbon dioxide
D) absorb solar energy
E) absorb carbon dioxide

A) NH₃, NH₄⁺, and NO₃-
B) NH₄⁺and NO₂-
C) N₂and NH₃
D) NH₄and NH₃
E) NO₃- and NO₄-

A) enters marine food webs
B) enters ocean plants
C) becomes ionized
D) precipitates out of solution
E) enters a gaseous phase

A) burning fossil fuels
B) deforestation
C) droughts
D) flooding
E) respiration due to overpopulation

A) increases in atmospheric concentrations of carbon dioxide
B) increases in extinction rates
C) increases in concentrations of carbon dioxide in soils
D) increases in carbon retention in animals
E) decreases in atmospheric concentrations of oxygen

A) Deforestation increases flooding.
B) New plant species that absorb less water were discovered.
C) Pollution gravely affected the water supply.
D) Primary consumers are the most important part of the energy pyramid.
E) Trees absorb too much water and are not useful in a watershed area.

A) CO₂
B) CaCO₃
C) C
D) HCO₃¯
E) N₂

A) increased frequency and severity of forest fires
B) increased logging
C) increased size of polar ice caps
D) sea level reductions
E) increased severity of volcanic eruptions

A) the architecture of the canopy of trees overhead
B) leaf positioning
C) leaf losses
D) timing of natural events
E) extent of agricultural practices

A) global warming
B) nitrogen fertilizer runoff
C) phosphorous fertilizer runoff
D) transfer of carbon dioxide from the atmosphere to the ocean
E) transfer of carbon dioxide from the ocean to the atmosphere

A) An increase in phytoplankton acidifies ocean water.
B) Phytoplankton are decomposed by aerobic bacteria, which depletes the surrounding water of oxygen.
C) Phytoplankton fix nitrogen in the water causing nitrification.
D) Phytoplankton are decomposed by anaerobic bacteria which enriches the surrounding water with oxygen.
E) Phytoplankton use up hydrogen ions, which decreases the acidity of the surrounding water.

A) climate change
B) the oceanic sink for carbon dioxide
C) gene expression in sea urchin larvae
D) genes expression in zooplankton
E) carbon dioxide accumulation in the ocean

A) ocean acidification
B) nitrogen fixation
C) soil runoff
D) declining primary productivity
E) depletion of oxygen in the oceans

A) HCO
B) HNO₃
C) CaCO₃
D) CO
E) H₂CO₃

A) irrigation
B) cutting down forests
C) using nitrogen-containing fertilizers
D) crop rotation
E) leaching

A) logging
B) farming
C) tree mortality rates
D) logging bans
E) fires

A) ocean acidification
B) nitrogen fixation
C) soil runoff
D) increasing droughts
E) depletion of oxygen in the atmosphere