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What Caused Pleistocene Cycles in Atmospheric CO2

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ALK'- Alkalinity = the total equivalence of ions that must be protonated in ... Inputs of ALK' to ocean are weathering of carbonates and weathering of silicates ... – PowerPoint PPT presentation

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Title: What Caused Pleistocene Cycles in Atmospheric CO2


1
What Caused Pleistocene Cycles in Atmospheric CO2
  • The Carbonate Mechanism

2
(No Transcript)
3
DIC ALK
  • CO2(g)? CO2(aq)
  • ? H2CO3 ?HHCO3- ? 2HCO32-
  • DIC- Dissolved inorganic carbon Sum off all
    these species
  • ALK- Alkalinity the total equivalence of ions
    that must be protonated in order to lower pH of
    seawater to the pKa of carbonic acid

4
Changing ALK to Deep Sea
  • Inputs of ALK to ocean are weathering of
    carbonates and weathering of silicates
  • Outputs are precipitation of CaCO3 and
    consumption of ALK by hydrothermal alteration
  • If increased weathering of carbonates in a
    glacial, or lessened coral reef growth, the deep
    sea inventories of DIC ALK would increase by
    12 ratio ? decrease CO2(atm)
  • Coral reef hypothesis- shift in locus of CaCO3
    deposition to deep sea (Berger 82 Opdyke and
    Walker 92)

5
The Lysocline
  • Increasing ALK to the deep sea increases CO32-
    which pushes the calcite saturation depth and the
    lysocline deeper
  • More area to precipitate CaCO3 over
  • Burial comes into equilibrium with increased ALK
    supply CO2 stabilises at lower value
  • Lysocline would deepen by 1km for 25ppmv
    decrease in CO2 associated with increased ALK
  • To match pCO2 changes calcite burial rate must
    have been 2-3 times today

6
Calcite Respiratory Dissolution
  • Significant dissolution of calcite occurs in
    response to the addition of CO2 to the pore water
    as oxic organic carbon degredation (Archer
    Maier-Reimer 1994)
  • Produces a minimum in CO32- at a depth of a few
    cm in sediment allowing dissolution, despite
    supersaturated overlying waters
  • Represents separation of saturation horizon and
    lysocline
  • Glacial times might have higher Corg/CaCO3 ratio
    of material reaching deep sea sediments more
    calcite respiratory disasolution

7
  • From Archer and Maier-Reimer 1994
  • Calcite respiratory dissolution allows lysocline
    and saturation horizon seperation, allows CO32-
    build up

8
Support
  • Glacial increased Corg production suggested by
  • Increased benthic-planktonic d13C gradients,
    increased sediment Corg from cores change in
    foraminiferal species
  • In general calcite organisms replaced by silicic
    diatoms
  • Front between Si CaCO3 production moved
    equatorwards
  • pH

9
Sanyal et al 1995
  • Boron isotopes from forams
  • Tropical surface waters pH 0.20.1pH units higher
    than Holocene
  • Tropical deep waters pH 0.30.1pH units higher
    than Holocene
  • If pH difference due to CaCO3 accumulation, ALK
    10 higher? CO32- 100µmolkg-1 higher ?
    deepening of calcite saturation by several km
  • Lysocline estimated only 700m deeper

10
Problems
  • If lysocline and saturation horizon was offset by
    several km in glacial times, would expect some
    significant separation today due to Corg rain
  • Transitition- pH estimates suggest 100µmolkg-1
    CO32- more than today, when excess Corg shut off
    lysocline drop below abyssal plains- mass calcite
    accumulation everywhere- CO32- drops lysocline
    rises and redissolves. Lack of evidence hard to
    believe

11
CaCO3 Compensation Model
  • At start of glacial excess metabolic CO2
    transferred from upper to deep ocean
  • Decrease ALKDIC ? less CO32- and dissolution of
    seafloor CaCO3
  • Raises ALKDIC in 21 ratio until new steady
    state
  • As initial CO2 addition was simple rearrangement
    within ocean, net ALKDIK gain hence lower pCO2

12
  • CO2 shift could be due to
  • i) Reduced ventilation of deep ocean around
    Antarctica
  • ii) Formation of low nutrient Glacial Atlantic
    Intermediate Water at expense of NADW
  • iii) More efficient Corg export due to increased
    nutrient supply
  • Results in upper ocean enriched in 13C and deep
    ocean depleated
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