Carbon Dioxide, Chemistry and Climate How do we know anything?

1. Climate Literacy Conference San Diego 18 Feb 2010 Carbon Dioxide, Chemistry and ClimateHow do we know anything? Ken CaldeiraCarnegie Institution Dept of Global EcologyStanford, CAkcaldeira@stanford.edu

2. How do we know anything? • Thought, intuition, interior reflection • Unplanned direct experience • Family, friends, etc • TV, magazines, books, web sites, blogs, experts, idiots • Planned empirical investigation • Careful analysis and appraisal of multiple sources of information

3. Can we trust our own experience? by Adrian Pingstone, based on the original created by Edward H. Adelson

4. Can we trust our own experience? by Adrian Pingstone, based on the original created by Edward H. Adelson

5. Can we trust our own experience? by Adrian Pingstone, based on the original created by Edward H. Adelson

7. How do we know anything? • What food to eat? • Which things are really dangerous? • Which investments are safe? • Whether human-induced climate change is a real threat? • Which energy technologies or approaches can really diminish climate risk?

9. Anthropogenic CO2 emissions exceed natural emissions by a factor of about 100

10. Fossil Fuel Emissions: Actual vs. IPCC Scenarios 10 CDIAC IEAall A1B(Av) 9 A1FI(Av) A1T(Av) A2(Av) 2005 B1(Av) 8 B2(Av) CO2 emissions (PgC y-1) Projection 7 6 5 1990 2000 2010 Updated Raupach et al. 2007, PNAS

11. Fossil Fuel Emissions: Actual vs. IPCC Scenarios 10 CDIAC IEAall A1B(Av) 9 A1FI(Av) 2006 A1T(Av) A2(Av) 2005 B1(Av) 8 B2(Av) CO2 emissions (PgC y-1) Projection 7 6 5 1990 2000 2010 Updated Raupach et al. 2007, PNAS

12. 2008 Fossil Fuel Emissions: Actual vs. IPCC Scenarios 10 CDIAC IEAall 2007 A1B(Av) 9 A1FI(Av) 2006 A1T(Av) A2(Av) 2005 B1(Av) 8 B2(Av) CO2 emissions (PgC y-1) Projection 7 6 5 1990 2000 2010 Updated Raupach et al. 2007, PNAS

13. Economic Crisis Impact on World GDP Growth -1.1% International Energy Agency, October 2009

14. 2009 2008 Projection 2009: Emissions: -2.8% GDP: -1.1% C intensity: -1.7% Fossil Fuel Emissions: Actual vs. IPCC Scenarios 10 CDIAC IEAall 2007 A1B(Av) 9 A1FI(Av) 2006 A1T(Av) A2(Av) 2005 B1(Av) 8 B2(Av) CO2 emissions (PgC y-1) Projection 7 6 5 1990 2000 2010 Raupach et al. 2007, PNAS; updated Raupach unpublished; Le Quéré et al. 2009, Nature-Geo, in press

15. Perturbation of Global Carbon Budget (1850-2006) 2000-2006 fossil fuel emissions 7.6 Source deforestation 1.5 CO2 flux (Pg C y-1) atmospheric CO2 4.1 Sink land 2.8 ocean 2.2 Time (y) Le Quéré, unpublished; Canadell et al. 2007, PNAS

16. Ice core and instrumental records of atmospheric carbon dioxide concentrations Petit et al (1999)

17. Fig by Robert A. Rohde

20. Ischia, Italy Map created by Norman Einstein

21. Low CO2= Native shellfish High CO2= Invasive grasses CO2 dissolving shells and skeletons Hall-Spencer / BBC Thanks, Jason Hall-Spencer

22. Chemistry ofocean acidification

23. Formation of calcium carbonate shells and skeletons CO32- H2O HCO3- H H O O O O O O O C C C O O O CO32- Ca H Ca2+ (dissolved)

24. Formation of calcium carbonate shells and skeletons CO32- H2O HCO3- H H O O O O O O O C C C O O O CO32- Ca H Ca2+ (dissolved)

25. Formation of calcium carbonate shells and skeletons CO32- H2O HCO3- H H O O O O O O O C C C O O O CO32- Ca H Ca2+ (dissolved)

26. Formation of calcium carbonate shells and skeletons H2O HCO3- H H O O O O O O O C C C O O O Ca CO32- H CaCO3 (solid)

27. Water, dissolved carbon, and shells and skeletons CaCO3 (solid) H2O HCO3- H H O O O O O O O C C C O O O Ca CO32- H

28. Addition of CO2 CaCO3 (solid) O C O CO2 H2O HCO3- H H O O O O O O O C C C O O O Ca CO32- H

29. Formation of carbonic acid H H HCO3- H2CO3 O O O O O O O O C C C C O O O O Ca CO32- H CaCO3 (solid)

30. Increasing ocean acidity H+ H HCO3- O O O O O O O O C C C C O O O O Ca CO32- H H HCO3- CaCO3 (solid)

31. Increasing ocean acidity H+ H HCO3- O O O O O O O O C C C C O O O O Ca CO32- H H HCO3- CaCO3 (solid)

32. Increasing ocean acidity H+ H HCO3- O O O O O O O O C C C C O O O O Ca CO32- H H HCO3- CaCO3 (solid)

33. Increasing ocean acidity CaCO3 (solid) H+ H HCO3- O O O O O O O O C C C C O O O O Ca CO32- H H HCO3-

34. Attacking a building block for shells and skeletons H+ H HCO3- O O O O O O O O C C C C O O O O Ca CO32- H H HCO3- CaCO3 (solid)

35. Attacking a building block for shells and skeletons HCO3- O O O O O O O O C C C C O O O O Ca HCO3- H H H HCO3- CaCO3 (solid)

36. Dissolving shells and skeletons CO32- HCO3- O O O O O O O O C C C C O O O O HCO3- Ca H Ca2+ (dissolved) H H HCO3-

37. Dissolving shells and skeletons CO32- HCO3- O O O O O O O O C C C C O O O O HCO3- Ca H Ca2+ (dissolved) H H HCO3-

38. Dissolving shells and skeletons CO32- HCO3- O O O O O O O O C C C C O O O O HCO3- Ca H Ca2+ (dissolved) H H HCO3-

40. Lizard IslandExpedition September 2008

41. We measured of coral skeletal growth rates 40% lower than in the late 1970’s

42. Distribution of corals andocean acidification

43. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

44. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

45. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

46. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

47. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

48. Carbon dioxide level,Coral reef distribution, and chemical conditions helping drive reef formation 0 1 2 3 4 5 ΩAragonite Corrosive Optimal Cao and Caldeira, 2008

50. Courtesy Lonnie Thompson