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In 1780, the famous English chemist Joseph Priestley (right) found that plants could "restore air which has been injured by the burning of candles." He used a mint plant, and placed it into an upturned glass jar in a vessel of water for several days. He then found that "the air would neither extinguish a candle, nor was it all inconvenient to a mouse which I put into it". In other words, he discovered that plants produce oxygen. A few years later, in 1794, the French chemist Antoine Lavoisier (left), discovered the concept of oxidation, but soon after was executed during the French Revolution for being a Monarchist sympathiser. The judge who pronounced sentence said "The Republic has no need for scientists".
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mass of the atmosphere: 5 x 10 18 kg
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Fast vertical mixing Mixing across tropopause is slow Fast vertical mixing Direct interface with surface T w/ altitude (adiabatic lapse rate) Rapid vertical mixing High T because of: high E of bomb. radiation Slow vertical mixing T w/ altitude because of h abs. by O 3 T w/ altitude because h abs. by O 3 less important
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© 2012 W. H. Freeman & Co.
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Skin cancer
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© 2012 W. H. Freeman & Co.
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14a–13
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(wavelength) x (frequency) = speed λν = c [3x10 8 m/s]
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E = h ν h = 6.6 x 10 -34 J.s Light as particles or photons With energy, E, proportional to frequency, ν
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=
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~ 450-750 nm Take 500 nm
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Copyright © Houghton Mifflin Company. All rights reserved. 14a–23 Electromagnetic spectrum λ ν
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E = h ν
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Chapman Mechanism (~1930, Sidney Chapman) O 2 + h O + O 498 kJ/mol <242.4 nm O + O 2 + M O 3 + M O 3 + h O + O 2 383 kJ/mol <280 nm
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Chapman Mechanism (~1930, Sidney Chapman) O 2 + h O + O 498 kJ/mol <242.4 nm O + O 2 + M O 3 + M O 3 + h O + O 2 383 kJ/mol <280 nm
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Chapman Mechanism (~1930, Sidney Chapman) O 2 + h O + O 498 kJ/mol <242.4 nm O + O 2 + M O 3 + M O 3 + h O + O 2 383 kJ/mol <280 nm
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Chapman Mechanism (~1930, Sidney Chapman) O 2 + h O + O 498 kJ/mol <242.4 nm O + O 2 + M O 3 + M O 3 + h O + O 2 383 kJ/mol <280 nm O + O 3 2O 2 O + O + M O 2 + M
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Ozone production λ ≤ 240 nm λ ≤ 280 nm h h Ozone destruction
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© 2012 W. H. Freeman & Co.
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λ ≥ 280 nm
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1 Dobson unit (DU) is: 0.01 mm of pure O 3 at 1 atm. and 0 o C NB: what does 300 DU expand to at 10 -6 atm?
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Ozone production Photochemical kinetics λ ≤ 240 nm λ ≤ 280 nm h h WRONG EQUILIBRIUM: TOO MUCH OZONE
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Chlorine reservoirs © 2012 W. H. Freeman & Co.
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Chlorine reservoirs © 2012 W. H. Freeman & Co.
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Recipe for ozone loss: 1.POLAR WINTER Polar vortex Isolates air 2.LOW TEMPERATURE PSC (=Polar Stratospheric Clouds) (=Nitric acid – HNO 3 ) 3.SURFACE CHEMISTRY Cl 2 (+denoxification) 4.LIGHT RETUNS Cl* Catalytic destruction of O 3
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Catalytic Decomposition of Ozone X + O 3 XO + O 2 XO + O X + O 2 _____________________________ O 3 + O 2O 2 X = HO x ( H, OH, HOO ) NO x (NO , NO 2 ) ClO x ( Cl, ClO )
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CHAPTER 02: Figure 2.1 © 2012 W. H. Freeman & Co.
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CHAPTER 02: Figure 2.2 © 2012 W. H. Freeman & Co.
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NASA projections of stratospheric ozone concentrations if chlorofluorocarbons had not been banned.
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Mount manitoba, June 1991
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CHAPTER 02: Figure 2.10 © 2012 W. H. Freeman & Co.
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PrefixMeaningAtoms in the Molecule CFCchlorofluorocarbonCl, F, C HCFChydrochlorofluorocarbonH, Cl, F, C HBFChydrobromofluorocarbonH, Br, F, C HFChydrofluorocarbonH, F, C HChydrocarbonH, C PFCperfluorocarbonF, C HalonN/A Br, Cl (in some but not all), F, H (in some but not all), C
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© 2012 W. H. Freeman & Co.
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