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Depletion Of The Ozone Layer Essay Research

Depletion Of The Ozone Layer Essay, Research Paper


The ozone layer diminishes more each year. As the area of


polar ozone depletion (commonly called the ozone hole) gets


larger, additional ultraviolet rays are allowed to pass through.


These rays cause cancer, cataracts, and lowered immunity to


diseases.1 What causes the depletion of the ozone layer?


In 1970, Crutzen first showed that nitrogen oxides produced


by decaying nitrous oxide from soil-borne microbes react


catalytically with ozone hastening its depletion. His findings


started research on "global biogeochemical cycles" as well as the


effects of supersonic transport aircraft that release nitrogen


oxide into the stratosphere.2


In 1974, Molina and Rowland found that human-made


chlorofluorocarbons used for making foam, cleaning fluids,


refrigerants, and repellents transform into ozone-depleting


agents.3


Chlorofluorocarbons stay in the atmosphere for several


decades due to their long tropospheric lifetimes. These compounds


are carried into the stratosphere where they undergo hundreds of


catalytic cycles with ozone.4 They are broken down into chlorine


atoms by ultraviolet radiation.5 Chlorine acts as the catalyst


for breaking down atomic oxygen and molecular ozone into two


molecules of molecular oxygen. The basic set of reactions that


involve this process are:


Cl + O3 –>ClO + O2 and


ClO + O –>Cl + O2


The net result:


O3 + O –>2O2


Chlorine is initially removed in the first equation by the


reaction with ozone to form chlorine monoxide. Then it is


regenerated through the reaction with monatomic oxygen in the


second equation. The net result of the two reactions is the


depletion of ozone and atomic oxygen.6


Chlorofluorocarbons (CFCs), halons, and methyl bromide are a


few of the ozone depletion substances (ODS) that break down ozone


under intense ultraviolet light. The bromine and fluorine in


these chemicals act as catalysts, reforming ozone (O3) molecules


and monatomic oxygen into molecular oxygen (O2).


In volcanic eruptions, the sulfate aerosols released are a


natural cause of ozone depletion. The hydrolysis of N2O5 on


sulfate aerosols, coupled with the reaction with chlorine in HCl,


ClO, ClONO2 and bromine compounds, causes the breakdown of ozone.


The sulfate aerosols cause chemical reactions in addition to


chlorine and bromine reactions on stratospheric clouds that


destroy the ozone.8


Some ozone depletion is due to volcanic eruptions. Analysis


of the El Chichon volcanic eruption in 1983 found ozone


destruction in areas of higher aerosol concentration (Hofmann and


Solomon, "Ozone Destruction through Heterogeneous Chemistry


Following the Eruption of El Chichon"). They deduced that the


"aerosol particles act as a base for multiphase reactions leading


to ozone loss."9 Chlorine and bromine cooperates with


stratospheric particles such as ice, nitrate, and sulfate to


speed the reaction. Sulfuric acid produced by eruptions enhances


the destructiveness of the chlorine chemicals that attack ozone.


Volcanically perturbed conditions increase chlorine’s breakdown


of ozone. Also, chlorine and bromine react well under cold


temperatures 15-20 kilometers up in the stratosphere where mos


of the ozone is lost. This helps explain why there is less ozone


in the Antarctic and Arctic polar regions.10, 11


The Antarctic ozone hole is the largest. A 1985 study


reported the loss of large amounts of ozone over Halley Bay,


Antarctica. The suspected cause was the catalytic cycles


involving chlorine and nitrogen.12


Halons, an especially potent source of ozone depleting


molecules, are used in fire extinguishers, refrigerants, chemical


processing. They are composed of bromine, chlorine, and carbon.


Most of the bromine in the atmosphere originally came from


halons

. Bromine is estimated to be 50 times more effective than


chlorine in destroying ozone.13


Insect fumigation, burning biomass, and gasoline usage all


release methyl bromide into the air. Some is recaptured before


reaching the stratosphere by soil bacteria and chemicals in the


troposphere. The remainder breaks down under exposure to


sunlight, freeing bromine to attack the stratospheric ozone.


Annual atmospheric releases of methyl bromide include 20 to 60


kilotons from fumigation (fifty percent of the methyl bromide


used as a soil fumigant is released into the atmosphere), 10 to


50 kilotons from biomass burning, and .5 to 1.5 kilotons from


leaded gasoline automobile exhaust each year. Marine plant life


also releases methyl bromide, but most is recaptured in seawater


reactions.14, 15


Hydrochlorofluorocarbons(HCFCs) and hydrofluorocarbons(HFCs)


are being used as substitutes to replace chlorofluorocarbons.


They "still contain chlorine atoms that are responsible for the


catalytic destruction of ozone but they contain hydrogen which


makes them vulnerable to the reaction with hydroxyl radicals (OH)


in the lower atmosphere.? The reactions in the troposphere remove


the chlorine before it reaches the stratosphere where ozone


depletion occurs.16


Some of the HFCs and HCFCs being used to replace CFCs are


HFC-134a, HCFC-22, HCFC-141b and HCFC-123. HFC-134a replaces CFC-


12 in most refrigeration uses. HCFC-22 is marketed as a coolant


for commercial and residential air-conditioning systems. HCFC-


141b and HCFC-123 are used for making urethane and other foams.1


Each year since the 1970s, the stratospheric ozone above


Antarctica disappears during September and reforms in November


when ozone-rich air comes in from the north. Because new


chemicals that do not destroy ozone are replacing ozone-depleting


chemicals, the ozone hole is projected to disappear by the middle


of the 21st century.18


References:


1. Monastersky, R. (1992, September 19). UV hazard: Ozone


lost versus ozone gained. Science News, 142, pp. 180-181.


2. Lipkin, R. (1995, October 21). Ozone Depletion research


wins Nobel. Science News, 148, pp. 262


3. Lipkin (ibid.)


4. Consortium for International Earth Science Information


Network(CIESIN) (1996, June, Version: 1.7). Chlorofluorocarbons


and Ozone Depletion. http://www.ciesin.org/TG/OZ/cfcozn.html


5. CIESIN (1996, June, Version: 1.7). Production and Use of


Chlorofluorocarbons. http://www.ciesin.org/TG/OZ/prodcfcs.html


6. CIESIN (1996, June, Version: 1.7). Ozone Depletion


Processes. http://www.ciesin.org/TG/OZ/ozndplt


7. US Environmental Protection Agency (1996). Ozone


Depletion Glossary. http://www.epa.gov/ozone/defns.html


8. National Oceanic and Atmospheric Administration (1994).


Scientific Assessment of Ozone Depletion-Executive Summary.


http://www.al.noaa.gov/WWWHD/pubdocs/Assessment94/executive-


summary.html#A


9. CIESIN (1996, June, Version 1.7). Ozone Depletion


Processes. (ibid.)


10. National Oceanic and Atmospheric Administration (1994).


Scientific Assessment of Ozone Depletion-Executive Summary.


(ibid.)


11. Kerr, Richard A. (1994, October 14). Antarctica Ozone


Hole Fails to Recover. Science, 266, pp.217


12. Kerr, Richard A. (ibid.)


13. US Environmental Protection Agency. Ozone Depletion


Glossary. (ibid.)


14. Adler, T. (1995, October, 28). Methyl Bromide doesn’t


stick around. Science News, 148, pp. 278


15. National Oceanic and Atmospheric Administration (1994).


Scientific Assessment of Ozone: 1994-Executive Summary. (ibid.)


16. CIESIN (1996, June, Version: 1.7). Ozone Depletion


Processes. (ibid.


17. CIESIN (1996, June, Version: 1.7). Ozone Depletion


Processes. (ibid.)


18. Monastersky, R. (1995, October 14). Ozone hole reemerges


above Atlantic. Science News, 148, pp. 245-246

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