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Class 3 Explaining the Present (Conclusion) And Projecting the Future

Class 3 Explaining the Present (Conclusion) And Projecting the Future. Climate Change OLLI Summer 2013. (Mostly) explaining the present. The Two Previous Coolings. Understanding the event Quantitative understanding comes after the event Qualitative understanding of second event by 1970s

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Class 3 Explaining the Present (Conclusion) And Projecting the Future

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  1. Class 3Explaining the Present (Conclusion)And Projecting the Future Climate Change OLLI Summer 2013

  2. (Mostly) explaining the present OLLI Climate Change - Summer 13

  3. OLLI Climate Change - Summer 13

  4. OLLI Climate Change - Summer 13

  5. OLLI Climate Change - Summer 13

  6. OLLI Climate Change - Summer 13

  7. The Two Previous Coolings • Understanding the event • Quantitative understanding comes after the event • Qualitative understanding of second event by 1970s • Made politically irrelevant by resumption of warming OLLI Climate Change - Summer 13

  8. The Late 19th-Early 20th Cooling:Dates and Terms • Last glacial maximum (LGM): 18,000 BP • Warming by fits and starts 18,000-12,000 BP • Holocene (“all of the new”): current interglacial • Begins at end of last glacial relapse (11,700 BP) • Preceded by Pleistocene (“most of the new”) – begins 2.6 MYA with onset of glaciations OLLI Climate Change - Summer 13

  9. Note: Due to smoothing, graph cannot resolve changes for periods shorter than 300 years. OLLI Climate Change - Summer 13

  10. From March 8, 2013 Science: “The general pattern of high-latitude cooling in both hemispheres opposed by warming at low latitudes is consistent with local mean annual insolation forcing associated with decreasing orbital obliquity since 9000 years ago (Fig. 2C). The especially pronounced cooling of the Northern Hemisphere extratropics, however, suggests an important role for summer insolation in this region, perhaps through snow-ice albedo and vegetation feedbacks.” “Our global temperature reconstruction for the past 1500 years is indistinguishable within uncertainty from the Mann et al. (2) reconstruction; both reconstructions document a cooling trend from a warm interval (~1500 to 1000 yrB.P.) to a cold interval (~500 to 100 yr B.P.), which is approximately equivalent to the Little Ice Age.” OLLI Climate Change - Summer 13

  11. 1940s-1970s Cooling • (Correct) contemporaneous understanding by 1970s • Two offsetting anthropogenic forces • Greenhouse effect of CO2 emissions • Increased albedo from sulfate aerosols • Talk of new “ice age” mostly in popular press • Lack tools for quantitative understanding OLLI Climate Change - Summer 13

  12. Computer Models • More powerful computers plus increased scientific understanding • Smaller grid cells –still too large for some features • Result • More confidence but little reduction in uncertainty range • Role for simpler models to permit multiple runs: intermediate complexity modesl OLLI Climate Change - Summer 13

  13. OLLI Climate Change - Summer 13

  14. The New Slowdown: Why This Time?Three Possibilities Plus a Fourth • Science is wrong • Atmosphere is saturated with greenhouse gases • GHG radiative forcing is being offset by increased albedo or reduced insolation • Changed distribution of thermal energy within Earth system OLLI Climate Change - Summer 13

  15. Distribution of Earth’s Thermal Energy • Vertical distribution between surface/lower atmosphere and upper atmosphere: primarily a measurement issue • Horizontal distribution over surface of land and ocean: the Manu Loa problem • Vertical distribution between surface and deep ocean OLLI Climate Change - Summer 13

  16. Role of the Oceans • Absorbs about a quarter of CO2 emissions • 90% of warming goes to heating the oceans • Two cycles: El Niño-Southern Oscillation (ENSO) and Interdecadal Pacific Oscillation (IPO) OLLI Climate Change - Summer 13

  17. ENSO and IPO • ENSO • Three to seven year cycle of varying strength • El Niño: reduced upwelling of cold deep water increases surface temperature and lowers deep ocean temperature • La Niña: reverse of El Niño • IPO • Can last two or three decades • Positive phase: • Increased tendency for El Niño • Weaker winds reduce circulation of heat to deep ocean • Negative phase: reverse of positive phase OLLI Climate Change - Summer 13

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  19. 1022 joules: annual output of a billion nuclear plants Volcanoes Strong El Nino Figure 1: Ocean Heat Content from 0 to 300 meters (grey), 700 m (blue), and total depth (violet) from ORAS4, as represented by its 5 ensemble members. OLLI Climate Change - Summer 13

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  21. Hiatus decade: negative surface warming. Accelerated warming decade: >0.41o – approximately twice recent decades “HC”: 2007 Harrison-Carson publication of ocean data OLLI Climate Change - Summer 13

  22. Current Explanation • Sulfate pollution and tropical volcanoes probably have played a role • Dominant force has been negative phase of IPO • Late 1970s: IPO enhanced greenhouse effect • Now working in opposite directions: increased surface winds increase ocean overturning • Scientific (and political question): when will IPO phase shift occur? OLLI Climate Change - Summer 13

  23. Questions • Scientific question: Explanation is immature: Is it correct? • Scientific and political question: When will the IPO reverse? • ENSO, IPO, South Asia monsoon: internal climate processes • Cannot reliably project timing or intensity OLLI Climate Change - Summer 13

  24. Projecting the future OLLI Climate Change - Summer 13

  25. IPCC 2007 Projections OLLI Climate Change - Summer 13

  26. How Warm Will It Get? • Behavioral issue: Future CO2 emissions • Scientific issue: Natural absorption of CO2 by ocean and biosphere • Behavioral issue: Human sequestration of CO2? • Scientific issue: Quantitative CO2-temperature relationship (climate sensitivity) OLLI Climate Change - Summer 13

  27. The Causal Chain (without radiation management) Carbon sequestration? Anthropogenic emissions Changes in natural carbon reservoirs Change in atmospheric concentration Climate sensitivity: T increase for doubling CO2 Change in Temperature Human behavior Science OLLI Climate Change - Summer 13

  28. They Weren’t Entirely Wrong • Don’t worry: oceans will absorb the CO2 • They don’t absorb all of it (Revelle and Keeling) • But much higher concentration without them • Don’t worry: the atmosphere already is saturated with greenhouse gases • More greenhouse gases mean more radiative forcing even at Venusian level • But an additional ton has a smaller impact at a higher concentration OLLI Climate Change - Summer 13

  29. Climate Sensitivity • Increase in equilibrium temperature from doubling CO2 concentration • Most estimates: 1.5o to 4.5o C • Not an estimate of temperature increase to 2100 • Calculating I mpact of increasing concentration: ΔT = ΔT2X * Ln(New CO2/Old CO2)/Ln(2), where temperatures are in degrees Kelvin OLLI Climate Change - Summer 13

  30. Logarithms • Power to which a base number must be raised in order to equal a certain number • Log10(100) = 2 because 102 =100 • Practical use (pre-computers) • Multiplication becomes addition • Raising to a power becomes multiplication • Today: describes relationship between two variables OLLI Climate Change - Summer 13

  31. Example: Increase from 280 ppm to 400 ppm • Linear relationship: 400/280 x 290o = 414o • Logarithmic relationship with sensitivity of 2o • Ln(400/280) = 0.36 • Ln(2) = 0.69 • 2 * 0.36/0.69 = 1.03o temperature increase OLLI Climate Change - Summer 13

  32. Difficulty of Determining Climate Sensitivity • Empirical • Temperature and CO2 at two points in time • Solve for climate sensitivity • Problems • Soldiers in a ditch • Equilibrium temperature OLLI Climate Change - Summer 13

  33. Soldiers in a Ditch • Task: Determine height of soldiers on other side of field • Known distance and surveying instruments • But they’re standing in a ditch • How deep is the ditch? We don’t know OLLI Climate Change - Summer 13

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  35. Equilibrium Temperature: Concepts • Thermal inertia • Cumulative and current forcing • Transient temperature • Equilibrium temperature OLLI Climate Change - Summer 13

  36. Forcing, Heat and Temperature • Forcing: Rate of change in Earth system heat content • Amount and rate of temperature change depend on system’s thermal inertia • Most heat content (and therefore most thermal inertia) is in ocean OLLI Climate Change - Summer 13

  37. Transient and Equilibrium Temperature • Thermal inertia  Temperature change lags behind change in forcing • Transient temperature – temperature on (e.g.) January 1, 2100 or day CO2 doubles • Equilibrium temperature: No net forcing –outgoing thermal and reflected solar equal incoming solar OLLI Climate Change - Summer 13

  38. Without Thermal Inertia • Earth system as a cheap aluminum pan • Instantaneous response to change in radiative balance: temperature always at equilibrium and no radiative forcing • “Transient temperature” is meaningless OLLI Climate Change - Summer 13

  39. Implications of Forcings as of 2005: Time and Inertia • Temperature increase to date: 0.70 C • Full response to ~one w/m2 of net forcing • Assuming ~1.85 w/m2cumulative net forcing since 1880, 0.85 w/m2 forcing still “in the pipeline” • Implies ~0.60further increase with no further change in GHG, aerosols, etc. OLLI Climate Change - Summer 13

  40. Cumulative forcing vs. current forcing • GHG concentration and albedo immediately changed to 2005 level in 1880 • Resulting forcing of 1.85 watts/m2 is cumulative forcing since 1880. • Partly “used up” since 1880 by temperature increase • If GHG concentration unchanged, further 0.7o temperature increase eliminates radiative forcing OLLI Climate Change - Summer 13

  41. Review of Measurement and Time • Sensitivities of temperature • To forcing: Stefan-Boltzmann equation • To GHG: climate sensitivity • Lag in full temperature impact • With positive forcing, equilibrium temperature > transient temperature: • With no changes in GHG or albedo, warming “in the pipeline” OLLI Climate Change - Summer 13

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  43. Possible vulnerability of projections OLLI Climate Change - Summer 13

  44. The Long Term • Short-term CO2 concentration: 50% absorbed, mostly in ocean • Good news: Cuts atmospheric increase in half • Bad news: ocean acidification • Long term: Next 1000 years dominated by ocean turnover • Absorbs CO2 -- reduces cumulative radiative forcing • Ocean warms – less heat transfer from atmosphere OLLI Climate Change - Summer 13

  45. Curves represent peak CO2 of 450 to 1200 ppm OLLI Climate Change - Summer 13

  46. What’s Happening? • At millennial time scale, CO2 largely equilibrates between ocean (~80%) and atmosphere (~20%) • Result: Radiative forcing reduced from peak • But oceans gradually warm • Result: reduced transfer of heat to ocean • Net result: near-constant temperature over millennium OLLI Climate Change - Summer 13

  47. What does 1000 years mean? • 1000 years ago • William the Conqueror not yet born • Not quite half way from Charlemagne to Thomas Aquinas • One percent annual growth in PCNP – increases 29000 times. OLLI Climate Change - Summer 13

  48. Policy Implications • We have to deal with additional warming • To avoid it, eliminate current radiative forcing without temperature increase • Immediately reduce GHG emissions below current level of their absorption by ocean and biosphere, or • Increase albedo OLLI Climate Change - Summer 13

  49. What do you want to (or think you’re able to) achieve? • Reduce ocean acidification: Only measures directed at GHG • Reduce global average temperature: Large-scale radiation management may be an alternative • Protect particular human/non-human populations or systems: Adaptation OLLI Climate Change - Summer 13

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