1. Climate Change: The Move to Action (AOSS 480 // NRE 480) Richard B. Rood Cell: 301-526-8572 2525 Space Research Building (North Campus) rbrood@umich.edu http://aoss.engin.umich.edu/people/rbrood Winter 2012 January 26, 2012

2. Class News Ctools site: AOSS_SNRE_480_001_W12AOSS_SNRE_480_001_W12 2008 and 2010 Class On Line:2008 and 2010 Class –http://climateknowledge.org/classes/index.php /Climate_Change:_The_Move_to_Actionhttp://climateknowledge.org/classes/index.php /Climate_Change:_The_Move_to_Action

3. Reading Response: Due Jan 31, 2012 The World Four Degrees Warmer –New et al. 2011New et al. 2011 Reading responses of roughly one page (single- spaced). The responses do not need to be elaborate, but they should also not summarize the reading. They should be used by you as think pieces to refine your questions and insight from the readings. They must be submitted via CTools at least two hours before the start of lecture for the relevant readings.

4. The Current Climate (Released Monthly) Climate Monitoring at National Climatic Data Center.Climate MonitoringNational Climatic Data Center –http://www.ncdc.noaa.gov/oa/ncdc.htmlhttp://www.ncdc.noaa.gov/oa/ncdc.html State of the Climate: Global Plant Hardiness - 2012

5. Some Project Ideas Education –Strategies when policy requires teaching “denial” –Incorporation into engineering curriculum –Earth science in K-12; admission to college Cities (esp Great Lakes) Adaptation Climate in the Keystone Pipeline Great Lakes Seasonal forecast information / Long-term projections / Use of information / Effectiveness of communication efforts

6. Today Scientific investigation of the Earth’s climate: Foundational information –Aerosols –Feedbacks

7. Scientific investigation of Earth’s climate SUNEARTH EARTH: EMITS ENERGY TO SPACE  BALANCE PLACE AN INSULATING BLANKET AROUND EARTH FOCUS ON WHAT IS HAPPENING AT THE SURFACE

8. Today Scientific investigation of the Earth’s climate: Foundational information –Radiative Balance –Earth System –Aerosols

9. Following Energy through the Atmosphere We have been concerned about, almost exclusively, greenhouse gases. –Need to introduce aerosols Continuing to think about –Things that absorb –Things that reflect

10. Aerosols Aerosols are particulate matter in the atmosphere. –They impact the radiative budget. –They impact cloud formation and growth.

11. Aerosols: Particles in the Atmosphere Aerosols: Particles in the atmosphere. Water droplets – (CLOUDS) “Pure” water Sulfuric acid Nitric acid Smog … Ice Dust Soot Salt Organic hazes AEROSOLS CAN: REFLECT RADIATION ABSORB RADIATION CHANGE CLOUD DROPLETS

12. Earth’s aerosols

13. Dust and fires in Mediterranean

14. Forest Fires in US

15. The Earth System Aerosols (and clouds) SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared) Clouds are difficult to predict or to figure out the sign of their impact Warmer  more water  more clouds More clouds mean more reflection of solar  cooler More clouds mean more infrared to surface  warmer More or less clouds? Does this stabilize? Water in all three phases essential to “stable” climate CLOUD

16. The Earth System: Aerosols SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared) Aerosols directly impact radiative balance Aerosols can mean more reflection of solar  cooler Aerosols can absorb more solar radiation in the atmosphere  heat the atmosphere In very polluted air they almost act like a “second” surface. They warm the atmosphere, cool the earth’s surface. AEROSOLS ? Composition of aerosols matters. This figure is simplified. Infrared effects are not well quantified

17. South Asia “Brown Cloud” But don’t forget –Europe and the US in the 1950s and 1960s Change from coal to oil economy

18. Coal emits sulfur and smoke particulates “Great London smog” of 1952 led to thousands of casualties. –Caused by cold inversion layer  pollutants didn’t disperse + Londoners burned large amounts of coal for heating Demonstrated impact of pollutants and played role in passage of “Clean Air Acts” in the US and Western Europe Asian Brown Cloud (But don’t forget history.)

19. Current Anthropogenic Aerosol Extreme South Asian Brown Cloud

20. Aerosol: South & East Asia http:// earthobservatory.nasa.gov/Newsroom/NasaNews/2001/200108135050.html

21. Reflection of Radiation due to Aerosol http:// earthobservatory.nasa.gov/Newsroom/NasaNews/2001/200108135050.html

22. Atmospheric Warming: South & East Asia http:// earthobservatory.nasa.gov/Newsroom/NasaNews/2001/200108135050.html WARMING IN ATMOSPHERE, DUE TO SOOT (BLACK CARBON)

23. Surface Cooling Under the Aerosol http:// earthobservatory.nasa.gov/Newsroom/NasaNews/2001/200108135050.html

25. Natural Aerosol

26. Earth’s aerosols

27. Volcanoes and Climate Alan Robock: Volcanoes and Climate Change (36 MB!)Alan Robock: Volcanoes and Climate Change (36 MB!) Alan Robock Department of Environmental Sciences

28. Explosive NET COOLING Stratospheric aerosols (Lifetime  1-3 years) Ash Effects on cirrus clouds absorption (IR) IR Heating emission IR Cooling More Downward IR Flux Less Upward IR Flux forward scatter Enhanced Diffuse Flux Reduced Direct Flux Less Total Solar Flux Heterogeneous  Less O 3 depletion Solar Heating H 2 S SO 2 NET HEATING Tropospheric aerosols (Lifetime  1-3 weeks) Quiescent SO 2  H 2 SO 4  H 2 SO 4 CO 2 H 2 O backscatter absorption (near IR) Solar Heating More Reflected Solar Flux Indirect Effects on Clouds Alan Robock Department of Environmental Sciences

29. Robock and Mao (1995) Superposed epoch analysis of six largest eruptions of past 120 years Year of eruption Significant cooling follows sun for two years Alan Robock Department of Environmental Sciences

30. The Earth System Aerosols (and clouds) SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared) Aerosols impact clouds and hence indirectly impact radiative budget through clouds Change their height Change their reflectivity Change their ability to rain Change the size of the droplets CLOUD

31. Aerosols and Clouds and Rain

32. Some important things to know about aerosols They can directly impact radiative budget through both reflection and absorption. They can indirectly impact radiative budget through their effects on clouds  both reflection and absorption. They have many different compositions, and the composition matters to what they do. They have many different, often episodic sources. They generally fall out or rainout of the atmosphere; they don’t stay there very long compared with greenhouse gases. They often have large regional effects. They are an indicator of dirty air, which brings its own set of problems. They are often at the core of discussions of geo-engineering

33. Scientific investigation of Earth’s climate

34. Today Scientific investigation of the Earth’s climate: Foundational information –Aerosols –Feedbacks

35. More consideration of radiative energy in the atmosphere FEEDBACKS.... –The idea that one thing causes a second thing to happen. That second thing then does something to the first thing –It damps it, negative feedback –It amplifies it, positive feedback –Technical Reference: Soden and HeldSoden and Held

36. The Earth System: Feedbacks 1 Infrared Proportional to Temperature SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared) Assume that greenhouse gases remain the same Infrared emission is proportional to temperature Temperature increases  emission increases

37. The Earth System: Feedbacks 2 Water Vapor When it gets warmer more water, a greenhouse gas, will be in the atmosphere Higher temperature increases evaporation from land and ocean Higher temperature allows air to hold more water Increase of water increases thickness of blanket – increases temperature more This could runaway! Natural limit because of condensation  clouds, rain? Compensating circulation changes? Think deserts … SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared)

38. The Earth System: Feedbacks 3 Ice - Albedo ICE Top of Atmosphere / Edge of Space When it gets warmer less ice Less ice means less reflection  warmer Warmer means less ice This could runaway! Cooler works the other way  ice-covered

39. The Earth System: Feedbacks 4 Clouds? SURFACE Top of Atmosphere / Edge of Space ATMOSPHERE (infrared) Clouds are difficult to predict or to figure out the sign of their impact Warmer  more water  more clouds More clouds mean more reflection of solar  cooler More clouds mean more infrared to surface  warmer More or less clouds? Does this stabilize? Water in all three phases essential to stable climate CLOUD

40. The Earth System: Feedbacks 5 Something with the Ocean? Is there something with the ocean and ice? Land ice melting decreases ocean salinity (density) Sea-ice impacts heat exchange between ocean and atmosphere Sea-ice impacts solar absorption of ocean North Atlantic sea-ice and ocean interaction very important to the climate Think Gulf Stream Think climate and people and economy Is there a natural feedback that stabilizes climate? Even if there is, it would be very disruptive, perhaps not stable from a societal point of view.

41. Cloud-Ice-Atmosphere Feedback Some carry away messages –This is where much of the discussion about scientific uncertainty resides. –The Earth is at a complex balance point That balance relies on water to exist in all three phases. –Too warm could run away to “greenhouse” vapor –Too cold run away to “snowball” ice –How clouds change is not well understood and much argued. The Iris Effect?The Iris Effect –Is there something in all of this that changes the sign; namely, that CO 2 warming will be compensated by more cooling?

42. CLOUD-WORLD Earth System: Ice ATMOSPHERE LANDOCEAN ICE (cryosphere) SUN ICE: Very important to reflection of solar radiation Holds a lot of water (sea-level rise) Insulates ocean from atmosphere (sea-ice) Ice impacts both radiative balance and water – oceans and water resources on land.. Large “local” effects at pole. Large global effects through ocean circulation and permafrost melting. Might change very quickly.

43. The Earth System: ICE (Think a little more about ice) non-polar glaciers and snow polar glaciers (Greenland) (Antarctica) sea-ice Impacts regional water supply, agriculture, etc. Solar reflection, Ocean density, Sea-level rise Solar reflection, Ocean-atmosphere heat exchange (Tour of the cryosphere, Goddard Scientific Visualization Studio)

44. The Cryosphere TOUR OF CRYOSPHERE: MAIN NASA SITETOUR OF CRYOSPHERE: MAIN NASA SITE

45. Let’s think about the Arctic for a while WWF: Arctic Feedbacks Assessment

46. Projected Global Temperature Trends: 2100 2071-2100 temperatures relative to 1961-1990. Special Report on Emissions Scenarios Storyline B2 (middle of the road warming). IPCC 2001

47. The Thermohaline Circulation (THC) (Global, organized circulation in the ocean) (The “conveyer belt”, “rivers” within the ocean) Where there is localized exchange of water between the surface and the deep ocean (convection) From Jianjun Yin, GFDL, see J. Geophysical Research, 2006 Warm, surface currents. Cold, bottom currents. Green shading, high salt Blue shading, low salt

48. The Earth System ATMOSPHERE LAND OCEAN ICE SUN Solar variability Water vapor feedback accelerates warming Ice-albedo feedback accelerates warming Increase greenhouse gases reduces cooling rate  Warming Changes in land use impact absorption and reflection Cloud feedback? Aerosols cool? Cloud feedback?

49. Scientific investigation of Earth’s climate SUNEARTH EARTH: EMITS ENERGY TO SPACE  BALANCE WHAT HAPPENS IF WE HAVE AN IMPULSE OR PERTURBATION TO THE SYSTEM?