Deck 55: Ecosystems and Restoration Ecology

A)tundra
B)savanna
C)salt marsh
D)open ocean
E)tropical rain forest

A)all of the brook trout in a 500 hectare² river drainage system
B)the plants, animals, and decomposers that inhabit an alpine meadow
C)a pond and all of the plant and animal species that live in it
D)the intricate interactions of the various plant and animal species on a savanna during a drought
E)interactions between all of the organisms and their physical environment in a tropical rain forest

A)producers.
B)producers and decomposers.
C)producers, primary consumers, and decomposers.
D)producers, primary consumers, secondary consumers, and decomposers.
E)producers, primary consumers, secondary consumers, top carnivores, and decomposers.

A)heterotrophs
B)herbivores
C)carnivores
D)primary consumers
E)secondary consumers

A)They recycle chemical elements directly back to primary consumers.
B)They synthesize organic molecules that are used by primary producers.
C)They convert organic materials from all trophic levels to inorganic compounds usable by primary producers.
D)They secrete enzymes that convert the organic molecules of detritus into CO₂ and H₂O.
E)Some species are autotrophic, while others are heterotrophic.

A)live organic material
B)detritus
C)fungi
D)other heterotrophs
E)bacteria

A)1%
B)10%
C)25%
D)50%
E)100%

A)synthesize organic compounds they obtain from decaying heterotrophs.
B)synthesize inorganic compounds from organic compounds.
C)use light energy to synthesize organic compounds.
D)use chemical energy to synthesize organic compounds.
E)convert light energy into matter.

A)is equal to NPP - respiration of autotrophs.
B)is about half of NPP.
C)is the total biomass of all photosynthetic autotrophs.
D)is the total energy from light converted to chemical energy of organic molecules per unit time.
E)is not as important as net primary production.

A)photosynthesis
B)heterotrophism
C)chemoautotrophism
D)thermophobism
E)chemosynthesis

A)Materials are repeatedly used, but energy flows through and out of ecosystems.
B)Both material and energy are recycled and are then transferred to other ecosystems as in a flow.
C)Materials are cycled into ecosystems from other ecosystems, but energy constantly flows within the ecosystem.
D)Both material and energy flow in a never-ending stream within an ecosystem.
E)None of the choices is correct.

A)Matter is cycled through ecosystems; energy is not.
B)Energy is cycled through ecosystems; matter is not.
C)Energy can be converted into matter; matter cannot be converted into energy.
D)Matter can be converted into energy; energy cannot be converted into matter.
E)Matter is used in ecosystems; energy is not.

A)tropical rain forest
B)tundra
C)benthic ocean
D)grassland
E)desert

A)Allow sheep to graze the lawn and then collect the sheep's feces to be delivered to the landfill.
B)Collect the lawn clippings and burn them.
C)Collect the lawn clippings and add them to a compost pile, don't collect the clippings and let them decompose into the lawn, or apply composted clippings to the lawn.
D)Collect the clippings and wash them into the nearest storm sewer that feeds into the local lake.
E)Dig up the lawn and cover the yard with asphalt.

A)primary consumer.
B)secondary consumer.
C)decomposer.
D)autotroph.
E)producer.

A)the energy contained in the standing crop
B)the energy used by heterotrophs in respiration
C)the energy used by autotrophs in respiration
D)the energy fixed by photosynthesis
E)all solar energy

A)Approximately 99% of the solar radiation is converted to heat energy.
B)Only 1% of the wavelengths of visible light are absorbed by photosynthetic pigments.
C)Most solar energy strikes water and land surfaces.
D)Approximately 99% of the solar radiation is reflected.
E)Only the green wavelengths are absorbed by plants for photosynthesis.

A)provide a nutritional resource for heterotrophs.
B)recycle chemical nutrients to a form capable of being used by autotrophs.
C)prevent the buildup of the organic remains of organisms, feces, and so on.
D)return energy lost to the ecosystem by other organisms.

A)light and nutrients
B)nutrients and temperature
C)light and temperature
D)light and phytoplankton
E)nutrients and wind

A)the ratio of net secondary production to assimilation of primary production.
B)the percentage of production transferred from one trophic level to the next.
C)a measure of how nutrients are cycled from one trophic level to the next.
D)usually greater than production efficiencies.
E)about 90% in most ecosystems.

A)Photosynthetic organisms absorb more visible light in the 350-750 wavelengths.
B)Satellite instruments can detect reflectance patterns of the photosynthetic organisms of different ecosystems.
C)Sensitive satellite instruments can measure the amount of NADPH produced in the summative light reactions of different ecosystems.
D)Satellites detect differences by comparing the wavelengths of light captured and reflected by photoautotrophs to the amount of light reaching different ecosystems.
E)Satellites detect differences by measuring the amount of water vapour emitted by transpiring producers.

A)energy converted by secondary consumers from primary consumers
B)solar energy that is converted to chemical energy by photosynthesis
C)food that is converted to new biomass by consumers
D)energy that is not used by consumers for growth and reproduction
E)growth that takes place during the second year of life in consumers

A)nitrogen
B)carbon
C)phosphorus
D)iron
E)zinc

A)savanna
B)open ocean
C)boreal forest
D)tropical rain forest
E)temperate forest

A)Top-level predators are destined to have small populations that are sparsely distributed.
B)Predators have relatively large population sizes.
C)Predators are more disease-prone than animals at lower trophic levels.
D)Predators have short life spans and short reproductive periods.
E)Top-level predators are more likely to be stricken with parasites.

A)biomass
B)standing crop
C)biomagnification
D)primary production
E)secondary production

A)pressure
B)lack of nutrients
C)light availability
D)herbivores
E)competition

A)gross primary productivity.
B)standing crop.
C)net primary productivity.
D)secondary productivity.
E)trophic efficiency.

A)light and nutrient availability
B)predation by primary consumers
C)increased pressure with depth
D)pollution
E)temperature

A)increased solar radiation
B)introduction of non-native tertiary consumer fish
C)nutrient runoff
D)accidental introduction of a prolific culture of algae
E)iron dust blowing into the lake

A)mammals, fish, insects
B)insects, fish, mammals
C)fish, insects, mammals
D)insects, mammals, fish
E)mammals, insects, fish

A)Oceans contain greater concentrations of nutrients compared to other ecosystems.
B)Oceans receive a lesser amount of solar energy per unit area.
C)Oceans have the largest area of all the ecosystems on Earth.
D)Ocean ecosystems have less species diversity.
E)Oceanic producers are generally much smaller than oceanic consumers.

A)the ratio of producers to consumers
B)the amount of heat energy released by the ecosystem
C)the net flux of CO₂ or O₂ in or out of an ecosystem
D)the rate of decomposition by detrivores
E)the annual total of incoming solar radiation per unit of area

A)Globally, phosphorous availability is most limiting to primary productivity.
B)Adding a nonlimiting nutrient will stimulate primary productivity.
C)Adding more of a limiting nutrient will increase primary productivity, indefinitely.
D)Phosphorous is sometimes unavailable to producers due to leaching.
E)Alkaline soils are more productive than acidic soils.

A)Fewer animals are slaughtered for human consumption.
B)There is an excess of plant biomass in all terrestrial ecosystems.
C)Vegetarians need to ingest less chemical energy than omnivores.
D)Vegetarians require less protein than do omnivores.
E)Eating meat is an inefficient way of acquiring photosynthetic productivity.

A)NPP can be expressed in energy/unit of area/unit of time.
B)NPP can be expressed in terms of carbon fixed by photosynthesis for an entire ecosystem.
C)NPP represents the stored chemical energy that is available to consumers in the ecosystem.
D)NPP is the same as the standing crop.
E)NPP shows the rate at which the standing crop is utilized by consumers.

A)temperature readings
B)potential evapotranspiration
C)intensity of solar radiation
D)annual precipitation
E)amount of carbon fixed

A)0.02%
B)1%
C)4%
D)10%
E)40%

A)open ocean because of the total biomass of photosynthetic autotrophs
B)grassland because of the small standing crop biomass that results from consumption by herbivores and rapid decomposition
C)tropical rain forest because of the massive standing crop biomass and species diversity
D)cave due to the lack of photosynthetic autotrophs
E)tundra because of the incredibly rapid period of growth during the summer season

A)Many primary and higher-order consumers are opportunistic feeders.
B)Decomposers compete with higher-order consumers for nutrients and energy.
C)Nutrient cycles involve both abiotic and biotic components of ecosystems.
D)Nutrient cycling rates tend to be limited by decomposition.
E)Energy transfer between tropic levels is in almost all cases less than 20% efficient.

A)nitrogen-ionic nitrogen in the soil
B)water-atmospheric water vapour
C)carbon-dissolved CO₂ in aquatic ecosystems
D)phosphorous-sedimentary rocks
E)All of the options are correct.

A)production efficiency - energy in assimilated food that is not used for respiration
B)secondary production - the amount of chemical energy in a consumers' food that is converted to their new biomass in a given time period
C)tertiary production - the number of top predators in the food web
D)trophic efficiency - percentage of production transferred from one trophic level to the next
E)eutrophication - excess nutrients resulting in high cyanobacteria concentrations and algae blooms

A)secondary consumers and top carnivores require less energy than producers.
B)at each step, energy is lost from the system as a result of keeping the organisms alive.
C)as matter passes through ecosystems, some of it is lost to the environment.
D)biomagnification of toxic materials limits the secondary consumers and top carnivores.
E)top carnivores and secondary consumers have a more general diet than primary producers.

A)Tropical bedrock contains little phosphorous.
B)Logging results in soil temperatures that are lethal to nitrogen-fixing bacteria.
C)Most of the nutrients in the ecosystem are removed in the harvested timber.
D)The cation exchange capacity of the soil is reversed as a result of logging.
E)Nutrients evaporate easily into the atmosphere in the post-logged forest.

A)Polar bears can provide more food for humans than seals can.
B)The total biomass of the fish is lower than that of the seals.
C)Seal meat probably contains the highest concentrations of fat-soluble toxins.
D)Seal populations are larger than fish populations.
E)The fish can potentially provide more food for humans than the seal meat can.

A)reversing the damage, adding fertilizer.
B)removing dams, increasing water flow.
C)adding soil, planting trees.
D)bioremediation, biological augmentation.
E)removing toxic soil, introducing fungi.

A)atmosphere
B)sedimentary bedrock
C)fossilized plant and animal remains (coal, oil, and natural gas)
D)plant and animal biomass
E)soil

A)0.01%
B)0.1%
C)1%
D)10%
E)60%

A)decomposition rate.
B)primary production.
C)density of primary consumers.
D)density of secondary consumers.
E)density of tertiary consumers.

A)atmosphere
B)sediments and sedimentary rocks
C)fossilized plant and animal remains (coal, oil, and natural gas)
D)plant and animal biomass
E)all of the above

A)O₂ released by oak trees in a forest
B)CO₂ absorbed by phytoplankton in the open ocean
C)excess NO₃⁻ converted to N₂ by denitrifying soil bacteria
D)phosphorous being absorbed from the soil by a corn plant
E)organic carbon remains of a leaf being converted to CO₂ by a fungus

A)0.1%
B)1%
C)10%
D)20%
E)80%

A)It is undigested and winds up in the feces and is not passed on to higher trophic levels.
B)It is used by organisms to maintain their life processes through the reactions of cellular respiration.
C)Heat produced by cellular respiration is used by heterotrophs to thermoregulate.
D)It is eliminated as feces or is dissipated into space as heat in accordance with the second law of thermodynamics.
E)It is recycled by decomposers to a form that is once again usable by primary producers.

A)producer level
B)primary consumer level
C)secondary consumer level
D)tertiary consumer level
E)decomposer level

A)Trees are generally less numerous in temperate forests, so fewer nutrients will be removed from the temperate forest ecosystem during a harvest.
B)Temperate forest tree species require fewer nutrients to survive than their tropical counterpart species, so a harvest removes fewer nutrients from the temperate ecosystem.
C)The warmer temperatures in the tropics influence rain forest species to assimilate nutrients more slowly, so tropical nutrient absorption is much slower than in temperate forests.
D)There are far fewer decomposers in tropical rain forests, so turning organic matter into usable nutrients is a slower process than in temperate forest ecosystems.
E)Typical harvests remove up to 75% of the nutrients in the woody trunks of tropical rain forest trees, leaving nutrient-impoverished soils behind.

A)Rhizobium bacteria.
B)nitrifying bacteria.
C)denitrifying bacteria.
D)methanogenic protozoans.
E)nitrogen-fixing bacteria.

A)The phosphorus cycle involves the recycling of atmospheric phosphorus.
B)The phosphorus cycle involves the weathering of rocks.
C)The carbon cycle is a localized cycle that primarily involves the burning of fossil fuels.
D)The carbon cycle has maintained a constant atmospheric concentration of CO₂ for the past million years.
E)The nitrogen cycle involves movement of diatomic nitrogen between the biotic and abiotic components of the ecosystem.

A)cellular respiration
B)photosynthesis
C)rock weathering
D)vulcanism
E)atmospheric phosphorous gas

A)N₂ in the atmosphere.
B)nitrite ions in the soil.
C)uric acid from animal excretions.
D)amino acids from decomposing plant and animal proteins.
E)nitrate ions in the soil.

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

A)5
B)6
C)7

A)Find out how much nitrogen is consumed in plant material by a Canada goose over about a 12-hour period, multiply this number by 100, and add that amount to the total nitrogen in the ecosystem.
B)Find out how much nitrogen is eliminated by a Canada goose over about a 12-hour period, multiply this number by 100, and subtract that amount from the total nitrogen in the ecosystem.
C)Find out how much nitrogen is consumed and eliminated by a Canada goose over about a 12-hour period and multiply this number by 100; enter this +/- value into the nitrogen budget of the ecosystem.
D)Do nothing. The Canada geese visitation to the lake would have negligible impact on the nitrogen budget of the pond.
E)Put a net over the pond so that no more migrating flocks can land on the pond and alter the nitrogen balance of the pond.

A)follow whale migrations in order to determine where most nutrients are located.
B)observe Antarctic Ocean productivity from year to year to see if it changes.
C)experimentally enrich some areas of the ocean and compare their productivity to that of untreated areas.
D)compare nutrient concentrations between the photic zone and the benthic zone in various marine locations.
E)contrast nutrient uptake by autotrophs in marine locations that are different temperatures.

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

A)C₃ plants are more efficient in their use of CO₂.
B)C₃ plants are able to obtain the same amount of CO₂ by keeping their stomata open for shorter periods of time.
C)C₄ plants don't use CO₂ as their source of carbon.
D)C₃ plants are more limited by CO₂ availability because they lack mechanisms to prevent transpirational water loss.
E)C₃ plants have special adaptations for CO₂ uptake, such as larger stomata.

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

A)hawk
B)snake
C)shrew
D)grasshopper
E)grass

A)hawk
B)snake
C)shrew
D)grasshopper
E)grass

A)greater than the biomass of A.
B)less than the biomass of H.
C)greater than the biomass of B.
D)less than the biomass of A + B.
E)less than the biomass of E.

A)5
B)6
C)7

A)An ecosystem's trophic structure determines the rate at which energy cycles within the system.
B)At any point in time, it is impossible for consumers to outnumber producers in an ecosystem.
C)Chemoautotrophic prokaryotes near deep-sea vents are primary producers.
D)There has been a well-documented increase in atmospheric nitrogen over the past several decades.
E)The reservoir of ecosystem phosphorous is the atmosphere.

A)to restore the physical structure
B)to restore native species that have been extirpated due to disturbance
C)to remove competitive invasive species
D)to identify the limiting factors of the producers
E)to remove toxic pollutants

A)A.
B)F.
C)C.
D)I.
E)E.

A)A
B)B
C)C
D)D
E)E

A)to replace a ruined ecosystem with a more suitable ecosystem for that area
B)to speed up the restoration of a degraded ecosystem
C)to completely restore a disturbed ecosystem to its former undisturbed state
D)to prevent further degradation by protecting an area with park status
E)to manage competition between species in human-altered ecosystems

A)A and B
B)A and D
C)B and C
D)C and D
E)C and E

A)A
B)B
C)C
D)D
E)E

A)A
B)B
C)C
D)D
E)E

A)0.03%
B)3%
C)10%
D)27%
E)33%