o 3 zone formation importance loss –pre 1974pre 1974 –pre 1985pre 1985 –post 1985post 1985...
TRANSCRIPT
O3zone• Formation• Importance• Loss
– pre 1974– pre 1985– post 1985
• Recovery• PSCs and Essential Chemistry• Ozone Hole 2015• Relationship to global warming
• The end
Relationship to Global Warming • Peripheral• Ozone has a slight greenhouse effect, but
• Loss of ozone over Antarctica may have intensified the polar vortex and reduced the warming expected in Antarctica
• CFCs are a significant green house gas
• Reduction of CFCs largest single human action mitigating the current warming
The End?• No, we have to limit the release of CFCs
into the atmosphere from now on.
• The good news - the atmosphere will cleanse itself of present atmospheric chlorine.
• The bad news - it will take another 50 years to see the ozone hole above Antarctica disappear.
Postscript• The ozone loss story is a positive one
• A global problem created by local human activities was identified, and reasonable solutions adopted by the worlds leading countries to reduce and eventually eliminate the problem.
• Is there a relation to global warming?
• Physically - minimal.
• Politically - the actions on ozone loss may serve as a model to direct future decisions by world leaders
Ozone Formation
• O2 + h O + O
• Then, O + O + M O2 + M
• or O + O2 + M O3 + M (Ozone created)– Where will this primarily occur?
• Also, O3 + h ( > 310 nm) O2 + O
• and O3 + h ( < 310 nm) O2* + O* (UV absorption)
• O2* + O2 2O2 + thermal energy (Excess energy dumped
• O2* O2 + h ( = 1.3 m) in ozone layer)
Importance of ozone• Absorbs DNA damaging UV radiation
– This UV affects both animals and plants
• SH/NH differences - In summer UV radiation is 50% more intense in SH than NH. Australia - world leader in skin cancer– Reasons – 10% - Earth is closer to sun in SH summer than
NH summer– 20% - Antarctic ozone loss/clearer atmosphere– 20% - Unknown
Food Preservation
• 100 BC - 1700s, Early methods: Drying, Salting, Cool cellars/Spring houses, Pickling, Fermenting, Canning.
• Cooking -> could eat spoiled food - spices to hide the flavor.
• 1803 Ice Boxes - Thomas Moore invented the insulated box, with ice was in a separate container above the food storage area. Relied on stores of natural ice from frozen lakes and rivers.
• 1850s - Methods to artificially produce ice were developed.
• 1890 - Warm weather/rain lead to a shortage of natural ice. Spurred the development of mechanical refrigeration.
Refrigeration• 1918 - Kelvinator, First refrigerator introduced to American market.
• 1920s - Refrigerators used ammonia (NH4), sulfur dioxide (SO2), (toxic, odorous), and methyl chloride (CH3Cl), (toxic, no odor) - silent killer.
• 1928 - Thomas Midgley, Fridgidaire, dichlorodifluoromethane (CCl2F2)
• 1929 - Fridgidaire and DuPont joined to produce CCl2F2, and CFCl3 as Freon.
CFCs• 1928 - First totally safe molecule for mechanical refridgerators - Thomas
Midgley, dichlorodifluoromethane (CCl2F2), Fridgidaire and DuPont joined to produce CCl2F2, and CCl3F as Freon (F12, F11).
• 1941 - Automobile air conditioning - Packard
• 1943 - Bug bomb used in WWII CFCs became propellants for aerosol spray cans.
• 1940 - 1960 - Uses of Freon boomed.
• 1970s - CFC production 600,000 tons annually growing 10% per year. Uses with immediate releases to the atmosphere - 66%, refrigeration - 20%
• 1971 - Lovelock - Electron Capture Device coupled with Gas Chromatography -> First capability to detect molecule concentrations on the order of ppt (parts per trillion = 10-12).
1974 - Molina and Rowland - simple question - What happens to CFCs released into the atmosphere? (awarded Nobel prize Chemistry 1995)
CCl3 F (F-11) + h ( < 240 nm, z > O3 layer) CCl2F + ClCCl2F2 (F-12) + h ( < 240 nm, z > O3 layer) CClF2 + Cl
• Then• Cl + O3 ClO + O2
• ClO + O Cl + O2
• Net: O3 + O O2 + O2
• This would occur above ozone layer altitudes above 30 km
Reservoir molecules
• 1975 - 1980 – Predicted ozone losses above 30 km were not observed. Reservoir molecules discovered.
– Cl + CH4 HCl + CH3
– ClO + NO2 ClONO2
– HCl and ClONO2 are reservoir species.1984 – Models predict 10% ozone loss in 100 years for current CFC production rates.
Ozone Profiles
McMurdo Station,
Antarctica
1986 - 1994
1994
1986 1987 1988
1989 1990 1991
1992 1993
Ozone Profiles
McMurdo Station,
Antarctica
1995 - 2000
1996 1997
1998 1999 2000
19951995 1996 1997
1998 19992000
Late winterspring
During Winter
Catalytic Cycle Polar Stratosphere– PSC particle + HCl + ClONO2 Cl2
– Cl2 + h Cl + Cl
– 2 [ Cl + O3 ClO + O]
– ClO + ClO + M ClOOCl + M (M=N2 or O2)
– ClOOCl + h Cl + ClOO
– ClOO + M Cl + O2 + M– h = Sun’s return
• Net 2O3 + h 3O2
• A single Cl atom can destroy more than100,000 ozone molecules.
• This cycle will continue until the NO2 and OH lost in the form of HNO3 in polar stratospheric clouds is replenished by mid latitude air, thus converting Cl back to its reservoir species.
Nitric acid/waterIce
Nitric acid/waterIce
Molina &Rowland,1974
ReservoirMoleculesDiscovered
MontrealProtocol, andamendments
Antarctic ozone holediscovered
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Refrigerants
Foam ExpansionSolventsPropellants
Fire Extinguishants
1974Ozone Depletion
Hypothesis
1986Base Year for
Montreal Protocol
1996CFC PhaseoutComplete in
Developed Countries
CFCs HCFCs HFCs
Refrigerants
Other
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An Industry in Transition
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Compliments of Paul Newmanand the Goddard automailer
Return
2014
McMurdo Antarctica78S - 1989
TroposphericChlorine