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Uncertainty, Lags, and Nonlinearity: Challenges to Governance in a Turbulent World

Uncertainty, Lags, and Nonlinearity: Challenges to Governance in a Turbulent World. Thomas Homer-Dixon CIGI Chair of Global Systems Balsillie School of International Affairs Waterloo,Canada May 7 2009. UNCERTAINTY LAGS NONLINEARITY OPENNESS. UNCERTAINTY LAGS NONLINEARITY OPENNESS.

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Uncertainty, Lags, and Nonlinearity: Challenges to Governance in a Turbulent World

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  1. Uncertainty, Lags, and Nonlinearity:Challenges to Governance in a Turbulent World Thomas Homer-Dixon CIGI Chair of Global Systems Balsillie School of International Affairs Waterloo,Canada May 7 2009

  2. UNCERTAINTY LAGS NONLINEARITY OPENNESS

  3. UNCERTAINTY LAGS NONLINEARITY OPENNESS

  4. UNCERTAINTY LAGS NONLINEARITY OPENNESS

  5. We need to shift from seeing the world as composed mainly of MACHINES to seeing it as composed mainly of COMPLEX SYSTEMS

  6. Whereas MACHINES • can be taken apart, analyzed, and fully understood (they are no more than the sum of their parts) • exhibit “normal” or equilibrium patterns of behavior • show proportionality of cause and effect, and • can be managed because their behavior predictable. . .

  7. COMPLEX SYTEMS • are more than the sum of their parts (they have emergent properties) • can flip from one pattern of behavior to another (they have multiple equilibriums) • show disproportionality of cause and effect (their behavior is often nonlinear, because of feedbacks and synergies), and • cannot be easily managed because their behavior is often unpredictable.

  8. We’re moving from a world of RISK to a world of UNCERTAINTY (unknown unknowns)

  9. So, we must move from “management” to Complex Adaptation

  10. Battisti and Naylor, “Historical warnings of future food insecurity with unprecedented seasonal heat.” Science (9 January 2009): 240-44

  11. Battisti and Naylor, “Historical warnings of future food insecurity with unprecedented seasonal heat.” Science (9 January 2009): 240-44

  12. IPCC 2007

  13. UNCERTAINTY LAGS NONLINEARITY OPENNESS

  14. LAGS • Between emission and climate response • Between cuts to emissions and reduction of warming • Between policy decision to change energy infrastructure and completion of this change

  15. “ [We show] that to hold climate constant at a given global temperature requires near zero future carbon emissions. . . . As a consequence, any future anthropogenic emissions will commit the climate system to warming that is essentially irreversible on centennial timescales.” Matthews, H. D., and K. Caldeira (2008), “Stabilizing climate requires near-zero emissions,” Geophys. Res. Lett.

  16. “[The] climate change that takes place due to increases in carbon dioxide concentration is largely irreversible for 1,000 years after emissions stop. Following cessation of emissions, removal of atmospheric carbon dioxide decreases radiative forcing, but is largely compensated by slower loss of heat to the ocean, so that atmospheric temperatures do not drop significantly for at least 1,000 years. Among illustrative irreversible impacts that should be expected if atmospheric carbon dioxide concentrations increase from current levels near 385 parts per million by volume (ppmv) to a peak of 450–600 ppmv over the coming century are dry-season rainfall reductions in several regions comparable to those of the ‘‘dust bowl’’ era and inexorable sea level rise.” Solomon et al, “Irreversible climate change due to carbon dioxide emissions,” PNAS (February 10 2009).

  17. Hansen, Atmos. Chem. Phys. 7 (2007): 2287-2312.

  18. UNCERTAINTY LAGS NONLINEARITY OPENNESS

  19. Ice Accumulation Rate (meters per year) Years before Present

  20. More rapid warming at poles One reason: Ice-albedo feedback Atmospheric warming radiative positive feedback, fast Increased ocean absorption of sun’s energy Melting of ice Lower reflectivity of ocean surface

  21. 2008 4.52 mK2

  22. Jakobshavn Ice Stream in Greenland Discharge from major Greenland ice streams is accelerating markedly. Source: Prof. Konrad Steffen, Univ. of Colorado

  23. Atmospheric warming carbon cycle positive feedback, potentially fast Death of forests Release of CO2 Rotting and burning of organic matter

  24. Atmospheric warming carbon cycle positive feedback, slow Increased airborne fraction Decreased efficiency of carbon sinks

  25. Up to 30 percent decrease in the efficiency of the Southern Ocean sink over the last 20 years Strengthening of the winds around Antarctica increases exposure of carbon-rich deep waters Strengthening of the winds due to global warming and the ozone hole Declining efficiency of the ocean sink Le Quéré et al. 2007, Science

  26. Atmospheric warming carbon cycle positive feedback, potentially fast Release of CH4 and CO2 Melting of permafrost Rotting of organic matter

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