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Download 2009, final Lecture 9 Marine Snow
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The Biological Pump Transfer of Energy and Material to the Deep Sea Formation and Fate of Marine Snow The ‘Missing’ Carbon Atmospheric Increases are ~3.2 Gt y-1 Anthropogenic inputs are ~5.4 Gt y-1 ~2.2 Gt of anthropogenic Carbon input is not accounted for in the atmosphere, and is therefore missing. The Biological Pump Marine Snow Marine Snow Particles Marine Snow Particles Discarded feeding houses Marine Snow Particles ‘Comets’ Contribution of Marine Snow to Vertical Flux Narrow window of particle sizes which are large enough to sink but numerous enough to be widely distributed. Cells Snow Bodies 2 200 20,000 (um) cell chain plankton poop aggregates Willie X 1-10 m 50 m Available to water column processes 100 m 2000 m Reduction in Vertical Flux over Depth 1 The Martin Curve 50% losses by 300 m 75% losses by 500 m 90% losses by 1500 m Martin and Knauer 1981 2 3 Explanations for the Shape of the Martin Curve • Bacterial decomposition = remineralization of Carbon • Cryptic swimmer distribution • Smaller, slower sinking particles at depth Extreme Deposition: Food Falls • Rare events (not recorded in traps) • Deposit large amounts of high quality organic materials to sea floor (low C:N) • Rapid sinking, reach 1000s of meters in few days • Large bodies that remain intact (whales, fish, macroalgae, etc) Aggregates Composition of Marine Snow Once living material (detrital) that is large enough to be seen by the unaided eye. Described first by Suzuki and Kato (1955) High C:N makes for poor food quality. • Senescent phytoplankton • Feeding webs (e.g., pteropods, larvaceans) • Fecal pellets • Zooplankton moults Formation of Marine Snow Type A: Mucous feeding webs are discarded individually. Type B: Smaller particles aggregate into larger, faster sinking particles. Aggregates How does Type B Snow Form? Coagulation Theory: Particle Collision Rates Differential settling velocities Turbulent motions How does Type B Snow Form? Coagulation Theory: Particle Stickiness Transparent Exopolymeric Particles TEPs Related to bloom conditions of phytoplankton: • High phyto concentration • Nutrient depletion • Self-sedimenting strategy? Properties of Type B Marine Snow • High porosity (99% water) • Carbon source for bacteria and protozoan grazers (gases often produced) • Some snow >90% bacteria • Pore water exchanges dictate chemical gradients Marine Snow Dynamics Where will Snow Contribute to Missing Carbon? Only ~1% of annual new production reaches sea floor
