1 / 17

Oceans and anthropogenic CO 2

Oceans and anthropogenic CO 2. By Monika Kopacz EPS 131. (Atmospheric) sources of anthropogenic CO 2. Fossil fuels (oil, gas, coal) Biomass burning (deforestation and others) Farming Land-use conversion Production of cement Total about 7 Pg (10 15 g) per year.

wray
Download Presentation

Oceans and anthropogenic CO 2

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Oceans and anthropogenic CO2 By Monika Kopacz EPS 131

  2. (Atmospheric) sources of anthropogenic CO2 • Fossil fuels (oil, gas, coal) • Biomass burning (deforestation and others) • Farming • Land-use conversion • Production of cement Total about 7 Pg (1015 g) per year

  3. Atmospheric concentration Figure adapted from Whitehouse Initiative on Global Climate Change

  4. What do we want to learn? • Anthropogenic CO2 presence in the oceans: sources, sinks, fluxes • Changes that have occurred so far, are occurring right now and are anticipated in the future • Should we be concerned or will Mother Nature heal itself?

  5. Box model of CO2 fluxes * Right now: not in steady state

  6. Figure adapted from Feely et al., 2001

  7. CO2 air-sea fluxes • Trends: • Equatorial Pacific: strong source of CO2 throughout the year • Subtropical oceans: upwelling and uptake depend on water temperature • High-latitude oceans: mostly deep water upwelling in the winter and biological uptake during spring and summer • Dependencies: Along with pressure differences, fluxes depend on gas transfer velocity (derived from other tracers), solubility (function of temperature and salinity)

  8. Facts about CO2 uptake • CO2 is more than twice soluble in cold water than in warm water • Marine phytoplankton transforms CO2 to organic carbon (Vertical gradient of dissolved inorganic carbon: 20% due to solubility pump, 80% due to biological pump)

  9. Calculating CO2 uptake • Using oceanic tracers such as carbon-14, tritium and chlorofluorocarbons (CFC’s) to: • directly measure fluxes into ocean and circulation within • simulate CO2 uptake and distribution with a model (based on previously measured quantities)

  10. Separating anthropogenic CO2 from natural From: Gruber, N., 1998: “Anthropogenic CO2 in the Atlantic Ocean.” Global Biogeochem. Cycles

  11. Separating anthropogenic CO2 from natural (contd.)

  12. Anthro- pogenic CO2 distribution Gruber, N., 1998: “Anthropogenic CO2 in the Atlantic Ocean.” Global Biogeochem. Cycles And “Global CO2 survey”

  13. Ocean as a sink for CO2: Solution to global warming?

  14. Ocean as a sink for CO2: Solution to global warming? Limitations to ocean CO2 uptake: limited buffering capability 

  15. Climate implications • Increased level of CO2 in surface water  30% decrease in carbonate ion by mid-century  reduction of coral reef * • More anthropogenic co2  Global warming  warming of the oceans  Slower circulation  another ice age * "Effect of calcium carbonate saturation state on the calcification rate of an experimental coral reef“ by Takahashi

  16. Ideas for restoring steady state • Sequestration • Collecting industrial CO2 and depositing it in deep ocean (>1000m), much like it is already being deposited in the earth

  17. Conclusions: • Ocean carbon cycle is currently not in steady state • Future climate change • Most realistic solution: decrease pollution

More Related