Transcript PPT

GEOLOGIC CARBON
CYCLE
• Textbook chapter 5, 6 & 14
• Global carbon cycle
• Long-term stability and feedback
Geological carbon cycle
Weathering of
rocks
Sediment burial
Williams and Follows (2011)
Volcanic degassing
Volcanic degassing
• Volcano
• Hydrothermal vents
• Very approximate carbon flux ~ 0.04 GTC/year
• Small carbon source relative to human emission, air-sea
CO2 exchange, biological productivity
• BUT it is dominant over long timescales ~ millions of
years+
Volcanic degassing
Equation for Ocean/Atmosphere
Carbon Inventory
dC
C
= flux dt
t
Steady State
0 = flux -
Timescale
C
t=
flux
C
t
Residence Time
Residence time
• (Residence time) = (Inventory) / (Flux)
Volcanic degassing
0.04 GTC/year
40, 000GTC
t =
0.04GTC / year
= 1,000,000 years
Ocean-atmosphere system
~ 40,000 GTC
Weathering
• Physical Weathering = mechanical breakdown of rocks
• Erosion
• Formation of sediments
• Chemical Weathering = chemical breakdown
• Salinity
• Some nutrients (silicate, phosphate)
• Alkalinity (Ca2+)
Weathering of Carbonate Rocks
1. Carbon dioxide is removed from the atmosphere by dissolving in water
and forming carbonic acid
CO2 + H2O -> H2CO3 (carbonic acid)
2. Carbonic acid is used to weather rocks (e.g. rain), yielding bicarbonate
ions, other ions, and clays, which are dumped into ocean (e.g. river runoff)
H2CO3 + H2O + silicate minerals -> HCO3- + cations (Ca++, Fe++, Na+, etc.) +
clays
3. Calcium carbonate is precipitated from calcium and bicarbonate ions in
seawater by marine organisms like coral, coccolithophores, foraminifera
Ca++ + 2HCO3- -> CaCO3 + CO2 + H2O (form both calcite and aragonite)
the carbon is now stored on the seafloor in layers of limestone
Formation of sediments
• Erosion and sediment transport
• Grain size scales and energy conditions
Seafloor sediments
Land origin
Plankton origin
marine snow
CCD = Calcite Compensation Depth
• Hard shell component of the marine snow
• Solubility of calcite depends on the pressure
• Calcite tends to dissolve in the deep ocean
CaCO3 (solid) «Ca2+ + CO32Above CCD, calcite is
preserved in the sediment
Below CCD, calcite is
dissolved and not
preserved in the sediment
Thermodynamic stability of CaCO3
• Solubility product Ksp
Ksp = [Ca 2+ ][CO32- ]sat
• Ksp increases with pressure
• Supersaturation above the calcite
saturation horizon
[CO32- ] > [CO32- ]sat
• Undersaturation below the
saturation horizon
[CO32- ] < [CO32- ]sat
Sarmiento and Gruber (2006)
Distribution of calcite on the seafloor
Chapter 5, Fig 17
Stability of calcite and pH
• Combination of DIC and Alk controls the acidity of
seawater.
[CO32- ] » Alk - DIC
• Increasing DIC increases acidity and lowers [CO32-].
• Once [CO32-] goes down below the thermodynamic
threshold [CO32-]sat, calcite is undersaturated and
dissolves in the water
CaCO3 (solid) « Ca 2+ + CO32Ksp = [Ca 2+ ][CO32- ]sat
Carbonate weathering cycle
• Carbonate weathering
• CaCO3 (land)  Ca2+ + CO32- (river input to the ocean)
 Formation of marine snow  CaCO3 (sediment)
• In a steady state (geological), no net addition of alkalinity or
DIC to the ocean-atmosphere system
Carbonate deposits
• The sink becomes the source
CaCO3 deposit from
coccolith-rich
sedimentary rock
Silicate weathering cycle
• Silicate weathering
• CaSiO3(land)+CO2(air) SiO2 + Ca2+ + CO32- (river input)
 SiO2(sediment) + CaCO3(sediment)
• Silicate weathering absorbs CO2 from the atmosphere, and
bury it into the sediment
 Net removal of CO2
Biogenic silica on the seafloor sediments
Chapter 5, Fig 15
Silica distribution in the surface ocean
Sarmiento and Gruber (2006)
Silicate weathering and CO2
• Volcanism  CO2 to the atmosphere
• Chemical breakdown of silicate rock  CO2 into the
ocean
• Burial of CaCO3  Plate tectonics  Subduction zone
Faint young sun paradox
• Sagan and Mullen (1972): In the early Earth, the solar
energy input was only about 70% of today but the climate
was as warm as today.
• Long-term stability of the
Earth’s climate system
• Temperature remained within
0°C and 100°C
Weathering-CO2 feedback
• Hypothesis: The speed of rocks’ chemical breakdown
partly depends on the temperature.
• Cold climate tends to slow down chemical weathering
• Slow-down of silicate weathering cannot balance volcanic CO2 flux
• Climate warms up due to increased atmospheric CO2
• Weathering-CO2 feedback tends to stabilize the climate
temperature over millions of years
• Is this sufficient to explain the early Earth’s warmth? Rosing et al.,
(2010) Nature: ongoing debate
Evidence for the weathering CO2
feedback?
• Ice core pCO2 for the last 800,000 years
• Very little long term trend
Modulation of weathering CO2 feedback
• Volcanic CO2 input
• The rate of plate subduction
• Calcite composition of subducting seafloor
• Weathering of silicate rock
• Mountain building
• Continent distribution
• Sea level
• Vegetation on land
Burial of organic carbon
• Sink of atmospheric CO2
• Removal of reduced carbon  Source of atmospheric O2
• Origin of fossil fuel
Photosynthesis and respiration
• Simplified representation of photosynthesis
• Most of the CH2O will return to CO2 via aerobic respiration
• Energy source for living organisms
• Small fraction of CH2O is buried on land and in the ocean sediments
• Increases atmospheric O2
Long-term controls on atmospheric O2
• Great O2 event = 2.5 billion years ago
• Early atmosphere had no oxygen.
• Oxygenation of the planet by biological O2 production
• O2 supports more complex, multi-cellular life
• Burial of organic matter balances organic C weathering
Organic Carbon-O2 feedback
• Hypothesis: Burial of organic carbon depends on the
oxygen content of the deep ocean
• If atmospheric O2 gets low, deep water goes anoxic
• Aerobic respiration stops and the respiration of organic matter
decreases
• More organic matter are preserved in the sediment
• Increases atmospheric O2
• This feedback can potentially stabilize the atmospheric
oxygen
• No quantitative model/theory yet
CaCO3 – pH feedback
• Why ocean pH is about 8?
 Carbonate chemistry
• DIC and alkalinity of seawater set pH of the seawater
• [CO32-] (≈ Alk – DIC) increases with pH
CaCO3 «Ca2+ +CO32• CaCO3-pH feedback
• If the ocean pH gets low, more CaCO3 dissolves at the seafloor.
• Dissolution of CaCO3 increases Alk relative to DIC
• pH increases
Fate of fossil fuel CO2
• CO2 emission into the atmosphere by human activities
(decades)
• Partial absorption into the land and upper ocean (decades)
• O(100-1,000 years)
• Equilibration of deep ocean carbon reservoir
• Absorbs 85% of carbon emission
• O(10,000+ years)
• Dissolution of seafloor CaCO3
• Increases alkalinity
• Absorbs remaining 15%
Theme III: long-term carbon-climate
relation
• Three stabilizing mechanisms for temperature, CO2,
alkalinity and pH of the seawater
• Operates over plate tectonic timescales, providing stability
to the climate and biogeochemical cycles
• Weathering-CO2 feedback
• Silicate weathering
• Organic Carbon-O2 feedback
• Preservation of organic matter on the seafloor
• CaCO3-pH feedback
• Preservation of CaCO3 on the seafloor
Changing mood of carbon cycle
• O(10-1k years)
Ocean carbon cycle acts as a sink of
carbon and heat, moderating the climate change
• O(100k years)
Ocean carbon cycle seems to act as
an amplifier of the glacial-interglacial climate change
• O(1 million years) Ocean carbon cycle seems to stabilize
the climate and cycling of elements through the three
feedbacks…
• Further reading: D. Archer (2010) “The Global Carbon
Cycle”, Princeton University Press.