energetics of marine ecosystems part i
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Energetics of Marine Ecosystems Part I. Section 3. Photosynthesis. Plants capturing sunlight Makes energy available to the food chain Source of energy for nearly all life on Earth - PowerPoint PPT PresentationTRANSCRIPT
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Energetics of Marine Ecosystems Part I
Section 3
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PhotosynthesisPlants capturing sunlight
Makes energy available to the food chainSource of energy for nearly all life on Earth
Green plants, including phytoplankton in aquatic food chains, capture light energy and use this to synthesize organic substances, including carbohydrates Converts light energy to chemical energy
glucose
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Phyto and Zoo PlanktonGreekPhyto = plantZoo = animalPlanktos = drifter;
wanderer
Phyto – autotrophsZoo – heterotrophs –
cannot produce own energyCnidarians –
jellyfishCrustaceans - krill
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ChlorophyllGreen pigment found in algae and plants that
allows them to absorb energy from lightGreek
Chloros – greenPhyllon – leaf
http://earthobservatory.nasa.gov/GlobalMaps/view.php?d1=MY1DMM_CHLORA
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Secchi DiscUsed to measure
light penetrationBlack and white
disc
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Secchi DiscDisc is lowered into water until no longer
visible – depth recordedThen slowly raised until seen again – depth
recordedMean of these two depths = transparency of
waterhttp://
www.mainevolunteerlakemonitors.org/recertify/disk.phpTurbidity = clarity
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Review: Marine Food Web(i) What is the primary
source of energy for this food web?
(ii) From the food web, write a complete food chain that has the least number of trophic levels.
(iii)Explain what the arrows between each organism represent.
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Answers(i) Sun/light; [1](ii) phytoplankton – krill – minke
whales/penguins - killer whales [1](iii) transfer of energy from each trophic
level;transfer of biomass from each trophic level;
[2]
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Deep OceanNot much light
penetrates deeper than 200m = 600 ft
Photosynthesis not possible
Producers (autotrophs = self feeders) here must find substances by other means
http://ocean.si.edu/deep-sea What lives here video
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Chemosynthesiscaptures the chemical
energy of dissolved mineralschemosynthetic bacteria at
hydrothermal vents make energy available to the food chain in the deep sea
Only some species of bacteria derive energy from the oxidation of inorganic substances (like hydrogen sulphide), and use this energy to synthesize organic compounds
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Hydrothermal VentsFluid emerging from hydrothermal vents is
rich in hydrogen sulphide and other gases. Chemosynthetic bacteria oxidize H2S and fix
CO2 to form organic substances Provide food source for animals in the hydrothermal
vent ecosystem Example: tube worm, giant clams
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RiftiaSymbiotic
relationship with chemosynthetic bacteriaProvide nutrients
TO Riftia
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Comparison: Chemo vs Photo
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ProductivityThe rate of accumulation/production of
biomass/energyBiomass = the mass of living biological organisms in
an ecosystem at a given timeMeasured in terms of energy capture per unit area
(or per unit volume in aquatic ecosystems) per yearAlmost all ecosystems = green plants are primary
producersRefer to primary production in relation to plants
Consumers depend directly or indirectly on the energy captured by primary producers
Productivity of an ecosystem affects all trophic levels
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ProductivityWhen conditions are favorable for
photosynthesis, the productivity of the ecosystem tends to be relatively high
Example: tropical rain forests, algal beds and reefs