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Presentation on theme: "Plankton."— Presentation transcript:

1 Plankton

2 Marine life 3 categories:
Benthos: bottom dwellers; sponges, crabs Nekton: strong swimmers- whales, fish, squid Plankton: animal/plants that drift in water. The have little control over their movement. Includes: diatoms, dinoflagellates, larvae, jellyfish, bacteria.

3 What physical factors are plankton subject to?
Waves Tides Currents

4 Plankton classified by:
Size Habitat Taxonomy

5 Size: Picoplankton (.2-2 µm) bacterioplankton
Nanoplankton ( µm) protozoans Microplankton ( µm) diatoms, eggs, larvae Macroplankton (200-2,000 µm) some eggs, juvenile fish Megaplankton (> 2,000 µm) includes jellyfish, ctenophores, Mola mola

6 Habitat: Holoplankton- spends entire lifecycle as plankton
Ex. Jellyfish, diatoms, copepods Meroplankton- spend part of lifecycle as plankton Ex. fish and crab larvae, eggs lobster snail fish

7 Habitat: Pleuston- organisms that float passively at the seas surface
Ex. Physalia, Velella Neuston – organisms that inhabit the uppermost few mm of the surface water Ex. bacteria, protozoa, larvae; light intensity too high for phytoplankton

8 Taxonomy

9 Blooms: High nutrients Upwelling Seasonal conditions
Phytoplankton- restricted to the euphotic zone where light is available for photosynthesis. Blooms: High nutrients Upwelling Seasonal conditions

10 Some important types of phytoplankton
Diatoms: temperate and polar waters, silica case or shell Dinoflagellates: tropical and subtropical waters.... also summer in temperate Coccolithophores: tropical, calcium carbonate shells or "tests" Silicoflagellates: silica internal skeleton... found world wide, particularly in Antarctic Cyanobacteria (blue-green algae): not true algae, often in brackish nearshore waters and warm water gyres Green Algae: not common except in lagoons and estuaries Some important types of phytoplankton Diatoms: Phylum Chrysophyta Dominant in temperate and polar waters Silica case or shell looks like a "pill box“; Found singly or in chains; Planktonic forms are radially symmetrical Can reproduce very quickly, up to 6x/day via asexual reproduction (also have sexual reproduction) Dinoflagellates Dominant in tropical and subtropical waters.... also summer in temperate areas they have two flagella and a shell of cellulose plates (called theca) Asexual reproduction and fast population growth can lead to "red tides" They secrete a neurotoxin called saxitoxin: bioaccumulates in shell fish and other filter feeders... can be fatal Coccolithophores Tropical... often very common Calcium carbonate shells or "tests" Their skeletons make important depositional structures, but "naked" forms are not preserved Silicoflagellates: Biflagellated, silica internal skeleton... found world wide, particularly in Antarctic Cyanobacteria: "Blue-green algae" but not true algae: often in brackish nearshore waters and warm water gyres these bacteria can fix gaseous nitrogen into NH4 Green Algae Not common except in lagoons and estuaries... often associated with coastal pollution Cryptomonad Flagellates: have chlorophyll a and c... adapted for turbid waters

11 Some important types of zooplankton
Crustaceans: Copepods Krill Cladocera Mysids Ostracods Jellies Coelenterates (True jellies, Man-of-wars, By-the-wind-sailors) Ctenophores (comb jellies) Urochordates (salps and larvacea) Worms (Arrow worms, polychaetes) Pteropods (planktonic snails)

12 Chaetognath

13 Copepod

14 Fish larvae

15 Jelly-like house Okiopleura Marine snow

16 Marine snow

17 Zooplankton: larvae, copepods. Some produce oil to help them float
Zooplankton: larvae, copepods. Some produce oil to help them float. Smaller population size than the phytoplanktoton. Zooplankton population size increases after phytoplankton size increases. zooplankton phytoplankton Winter Spring Summer Fall

18 Nutritional modes of zooplankton:
Herbivores: feed primarily on phytoplankton Carnivores: feed primarily on other zooplankton (animals) Detrivores: feed primarily on dead organic matter (detritus)  Omnivores: feed on mixed diet of plants and animals and detritus

19 Diurnal vertical migration

20 Vertical Migration

21 Diel vertical Migration
Each species has its own preferred day and night depth range, which may vary with lifecycle. Nocturnal Migration single daily ascent near sunset Twilight migration (crepuscular period) two ascents and two descents Reverse migration rise during day and descend at night

22 Advantages for Diurnal vertical migration
An antipredator strategy; less visual to predators Zooplankton migrate to the surface at night and below during the day to the mesopelagic zone. Copepods avoid euphasiids which avoid chaetognaths.

23 Advantages for DVM 1. Energy conservation Encounter new feeding areas
Get genetic mixing of populations Hastens transfer of organic material produced in the euphotic zone to the deep sea

24 Plankton Patchiness Zooplankton not distributed uniformly or randomly
Aggregated into patches of variable size Difficult to detect with plankton nets - Nets “average” the catch over the length of the tow May explain enormous variability in catches from net tows at close distances apart Plankton Patchiness In the ocean, zooplankton do not occur evenly or randomly. The are aggregated into patches that occur in both the horizontal and vertical. These patches may be a few centimeters in scale or s of kilometers. Traditional sampling tools do a poor job of detecting this patchiness because they average the catch over the length of the tow. This patchiness may explain why there is so much variability in repeated net tows taken in close proximity to each other.

25 Problems Detecting Patches with Nets
Nets are poor tools for looking at the fine-scale (meters-km) patchiness of plankton. Consider this example. We tow a plankton net with a diameter of 1 m along a 400 m distance. We will filter about 400 cubic meters of water. In the first example, all the copepods in the water are in one place about half way along the tow. In the bottom example, all the copepods are distributed fairly evenly along the tow. In both cases we wind up with 11 copepods/400 cubic meters or copepods/cubic meter. Can we determine where the copepods were concentrated along the tow path? Unfortunately not. To do that we need to use other tools such as towed video camera systems and pumps.

26 Causes of Patchiness Aggregations around phytoplankton
- If phytoplankton occurs in patches, grazers will be drawn to food - Similar process that led to phytoplankton patches will form zooplankton patches Grazing “holes” Physical process - Langmuir Cells - Internal waves Causes of Patchiness We saw a number of mechanisms that led to patches of phytoplankton. Feeding on patches of phytoplankton will also lead to formation of patches of zooplankton. Other mechanisms that we’ll take a look at include grazing holes created by predators and physical processes such as Langmuir cells and Internal Waves.

27 Grazing Holes When predators swim through a patch of plankton, they will remove animals along their path. These holes create patches. This image is another example of how vertical migration and predation interact to create patches. Fieberling Guyot is a seamount in the Pacific. The rocks on the seamount are covered with benthic organisms that feed on plankton. At night the zooplankton migrate to the surface to feed. At dawn they migrate down; however, many of those that migrate down over the seamount are lost to predators on the seamount. When they rise the next evening, there is a hole over the seamount where animals were consumed. This image shows patches of plankton after several nights on the seamount. Note the hole near the top of the seamount and higher amounts of plankton away from the seamount. The holes are not exactly over the seamounts because of horizontal currents.

28 Accumulation of Plankton in Langmuir Cells
Buoyant particles and upward-swimming zooplankton will accumulate over downwelling zones Accumulation of Plankton in Langmuir Cells Animals that can swim upwards against the downward water flow will concentrate in the slick. Similarly, buoyant particles such as bubbles, floating seaweed and debris will also accumulate in the slicks.

29 Langmuir Cells First noted by Irving Langmuir when crossing the Atlanice. He saw long bands of floating Sargassum seaweed aligned in the direction of the wind. These observations prompted him to carry out a series of experiments in a lake to find the process which had produced these bands. The stress of the wind blowing across the surface of the water gives rise to vertically circulating Langmuir Cells in the water.

30 Langmuir Cells At the boundary of two cells, the water will either flow upwards towards the surface or downwards. Downward flows will appear as slicks (shiny smooth water) while upward flows will appear as rough, rippled areas. Zooplankton and flotsam can accumulate in the downward convergences.

31 Internal Waves Internal waves are underwater waves that propagate along the pycnocline. If youÕve ever seen those wave toys that have bluewater and clear oil in them inside of a plexiglas box, youÕve seen something like an internal wave. They form when tidal currents flow over jumps in the bathymetry (for example over the edge of the continental shelf or a submarine bank). Their height can be much greater than surface waves because the effects of gravity are less pronounced. From the surface on a calm day, you can often see internal waves as a series of slicks on the water surface

32 Internal Waves These internal wave slicks were photographed during the summer off Mississippi sound. Notice the roughly parallel slicks on the surface. These slicks represent zones of downwelling and the rough areas between them are zones up upwelling. Zooplankton can be concentrated in these slicks in much the same way that they are concentrated over downwelling zones in Langmuir cells. These examples are just a few of the ways that physical processes can interact with biology to generate patches of plankton. Your textbook contains several other examples.

33 Deep sea scattering layer:
Composite echogram of hydroacoustic data showing a distinct krill scattering layer. Black line represents surface tracking of a blue whale feeding patchiness

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