Path: senator-bedfellow.mit.edu!bloom-beacon.mit.edu!boulder!spot.colorado.edu!rparson From: rparson@spot.colorado.edu (Robert Parson) Newsgroups: sci.environment,sci.answers,news.answers Subject: Ozone Depletion FAQ Part III: The Antarctic Ozone Hole Followup-To: poster Date: 24 Dec 1997 20:50:47 GMT Organization: University of Colorado, Boulder Lines: 1042 Approved: news-answers-request@MIT.Edu Expires: Sun, 1 Feb 1998 00:00:00 GMT Message-ID: <67rsj7$2un@peabody.colorado.edu> Reply-To: rparson@spot.colorado.edu NNTP-Posting-Host: spot.colorado.edu NNTP-Posting-User: rparson Summary: This is the third of four files dealing with stratospheric ozone depletion. It describes the massive losses measured in the Antarctic spring, and the smaller losses seen in the Arctic. Keywords: ozone layer hole cfc stratosphere antarctic arctic ClO Originator: rparson@spot.colorado.edu Xref: senator-bedfellow.mit.edu sci.environment:158519 sci.answers:7561 news.answers:119777 Archive-name: ozone-depletion/antarctic Last-modified: 16 Dec 1997 Version: 5.9 ----------------------------- Subject: How to get this FAQ These files are posted to the newsgroups sci.environment, sci.answers, and news.answers. They are also archived at a variety of sites. These archives work by automatically downloading the faqs from the newsgroups and reformatting them in site-specific ways. They usually update to the latest version within a few days of its being posted, although in the past there have been some lapses; if the "Last-Modified" date in the FAQ seems old, you may want to see if there is a more recent version in a different archive. Many individuals have archived copies on their own servers, but these are often seriously out of date and in general are not recommended. A. World-Wide Web (Limited) hypertext versions, with embedded links to some of the on-line resources cited in the faqs, can be found at: http://www.faqs.org/faqs/ozone-depletion/ http://www.cis.ohio-state.edu/hypertext/faq/usenet/ozone-depletion/top.html http://www.lib.ox.ac.uk/internet/news/faq/sci.environment.html http://www.cs.ruu.nl/wais/html/na-dir/ozone-depletion/.html Plaintext versions can be found at: ftp://rtfm.mit.edu/pub/usenet/news.answers/ozone-depletion/ ftp://ftp.uu.net/usenet/news.answers/ozone-depletion/ ---- B. Anonymous ftp To rtfm.mit.edu, in the directory /pub/usenet/news.answers/ozone-depletion To ftp.uu.net, in the directory /usenet/news.answers/ozone-depletion Look for the four files named intro, stratcl, antarctic, and uv. ---- C. Regular email Send the following messages to mail-server@rtfm.mit.edu: send usenet/news.answers/ozone-depletion/intro send usenet/news.answers/ozone-depletion/stratcl send usenet/news.answers/ozone-depletion/antarctic send usenet/news.answers/ozone-depletion/uv Leave the subject line blank. If you want to find out more about the mail server, send a message to it containing the word "help". ----------------------------- Subject: Copyright Notice *********************************************************************** * Copyright 1997 Robert Parson * * * * This file may be distributed, copied, and archived. All such * * copies must include this notice and the paragraph below entitled * * "Caveat". Reproduction and distribution for personal profit is * * not permitted. If this document is transmitted to other networks or * * stored on an electronic archive, I ask that you inform me. I also * * ask you to keep your archive up to date; in the case of world-wide * * web pages, this is most easily done by linking to the master at the * * ohio-state http URL instead of storing local copies. Finally, I * * request that you inform me before including any of this information * * in any publications of your own. Students should note that this * * is _not_ a peer-reviewed publication and may not be acceptable as * * a reference for school projects; it should instead be used as a * * pointer to the published literature. In particular, all scientific * * data, numerical estimates, etc. should be accompanied by a citation * * to the original published source, not to this document. * *********************************************************************** ----------------------------- Subject: General Information about this part This part deals specifically with springtime antarctic ozone depletion (and with the similar but smaller effects seen in the Arctic spring). More general questions about ozone and ozone depletion, including the definitions of many of the terms used here, are dealt with in parts I and II. Biological effects of the ozone hole are dealt with in part IV. ----------------------------- Subject: Caveats, Disclaimers, and Contact Information | Caveat: I am not a specialist. In fact, I am not an atmospheric | chemist at all - I am a physical chemist who talks to atmospheric | chemists. These files are an outgrowth of my own efforts to educate | myself over the past two years. I have discussed some of these | issues with specialists but I am solely responsible for everything | written here, including any errors. On the other hand, if you find | this document in an online archive somewhere, I am not responsible for | any *other* information that may happen to reside in that archive. | In general this document should not be cited in publications off the | net; rather, it should be used as a pointer to the published literature. *** Corrections and comments are welcomed. - Robert Parson Associate Professor Department of Chemistry and Biochemistry, University of Colorado (for which I do not speak) rparson@spot.colorado.edu Robert.Parson@colorado.edu ----------------------------- Subject: TABLE OF CONTENTS How to get this FAQ Copyright Notice General Information about this part Caveats, Disclaimers, and Contact Information TABLE OF CONTENTS 1.) What is the Antarctic ozone hole? 2.) Where can I find pictures of the ozone hole on the net? 3.) How big is the hole, and is it getting bigger? 4.) When did the hole first appear? 5.) How far back do antarctic ozone measurements go? 6.) But I heard that Dobson saw an ozone hole in 1956-58... 7.) Why is the hole in the Antarctic? a.) The Polar Vortex b.) Polar Stratospheric Clouds ("PSC") c.) Reactions On Stratospheric Clouds d.) Sedimentation and Denitrification e.) Photolysis of active chlorine compounds f.) Catalytic destruction of ozone by active chlorine 8.) What is the evidence for the present theory? 9.) Will the ozone hole keep growing? a.) Lateral Extent b.) Vertical Depth c.) Duration of the hole 10.) Why be concerned about an ozone hole over antarctica? 11.) Is there an ozone hole in the arctic? 12.) Can the hole be "plugged"? REFERENCES FOR PART III Introductory Reading Books and Review Articles More Specialized References ----------------------------- Subject: 1.) What is the Antarctic ozone hole? For the past decade or so, ozone levels over Antarctica have fallen to abnormally low values between August and late November. At the beginning of this period, ozone levels are already low, about 300 Dobson units (DU), but instead of slowly increasing as the light comes back in the spring, they drop to 150 DU and below. In the lower stratosphere, between 15 and 20 km, about 95% of the ozone is destroyed. Above 25 km the decreases are small and the net result is a thinning of the ozone layer by about 50%. In the late spring ozone levels return to more normal values, as warm, ozone-rich air rushes in from lower latitudes. The precise duration varies considerably from year to year; in 1990 the hole lasted well into December. In some of the popular newsmedia, as well as many books, the term "ozone hole" is being used far too loosely. It seems that any episode of ozone depletion, no matter how minor, now gets called an ozone hole (e.g. 'ozone hole over Hamburg - but only for one day'). This sloppy language trivializes the problem and blurs the important scientific distinction between the massive ozone losses in polar regions and the much smaller, but nonetheless significant, ozone losses in middle latitudes. It is akin to using "gridlock" to describe a routine traffic jam. ----------------------------- Subject: 2.) Where can I find pictures of the ozone hole on the net? The best-known images are those from the TOMS instrument on the Nimbus-7 satellite. These are available at http://jwocky.gsfc.nasa.gov/multi/multi.html Gifs, sound files, and a short movie (mpeg or quicktime) are included. Some other Web sites that carry ozone hole images include the International Centre for Antarctic Information and Research (ICAIR) in New Zealand: http://icair.iac.org.nz/ozone/index.html the JPL images archive: http://www.jpl.nasa.gov/archive/images.html (Look for the file ozone93b.gif. If you do not have web access you can get it by anonymous ftp to ftp.jpl.nasa.gov in the directory pub/images/browse.) and a gopher menu at the University of Michigan: gopher://blueskies.sprl.umich.edu/11/ The vertical distribution of ozone in the hole is shown dramatically in a series of images archived at: http://www.awi-bremerhaven.de/MET/Neumayer/ozone.html Some plots showing how the size and depth of the ozone hole has changed from year to year can be found at the EASOE home page: http://www.atm.ch.cam.ac.uk/images/easoe/ The Antarctic Ozone Hole was discovered by the British Antarctic Survey, and more information can be found on their web page: http://www.nbs.ac.uk/public/icd/ozone_pub/index.html A movie illustrating the dynamics of the antarctic vortex can be found at http://daac.gsfc.nasa.gov/CAMPAIGN_DOCS/UARS_project.html Lenticular Press publishes a multimedia CD-ROM (for Apple Macintosh) containing ozone data and images, as well as a hypertext document similar to this FAQ. For sample images and information about ordering the CD, see http://www.lenticular.com/ Note that these samples are copyrighted and may not be further distributed. ----------------------------- Subject: 3.) How big is the hole, and is it getting bigger? During the years 1978-1987 the hole grew, both in depth (total ozone loss in a column) and in area. This growth was not monotonic but seemed to oscillate with a two-year period (perhaps connected with the "quasibiennial oscillation" of the stratospheric winds.) The hole shrank dramatically in 1988 but in 1989-1991 was as large as in 1987, and in 1992-95 was larger still. In 1987 and 1989-95 it covered the entire Antarctic continent and part of the surrounding ocean. The exact size is determined primarily by meteorological conditions, such as the strength of the polar vortex in any given year. The boundary is fairly steep, with decreases of 100-150 DU taking place in 10 degrees of latitude, but fluctuates from day to day. On occasion, the nominal boundary of the hole has passed over the tip of S. America, (55 degrees S. Latitude). Australia and New Zealand are far outside the hole, although they do experience ozone depletion, more than is seen at comparable latitudes in the Northern hemisphere. After the 1987 hole broke up, December ozone levels over Australia and New Zealand were 10% below normal. [WMO 1991] [Atkinson et al.] [Roy et al.]. ----------------------------- Subject: 4.) When did the hole first appear? It was first observed by ground-based measurements from Halley Bay on the Antarctic coast, during the years 1980-84. [Farman, Gardiner and Shanklin.] (At about the same time, an ozone decline was seen at the Japanese antarctic station of Syowa; this was less dramatic than those seen at Halley since Syowa is about 1000 km further north, and did not receive as much attention.) It has since been confirmed by satellite measurements as well as ground-based measurements elsewhere on the continent, on islands in the Antarctic ocean, and at Ushaia, at the tip of Patagonia. With hindsight, one can see the hole beginning to appear in the data around 1976, but it grew much more rapidly in the 1980's. [Stolarski et al. 1992] ----------------------------- Subject: 5.) How far back do antarctic ozone measurements go? Ground-based measurements began in 1956, at Halley Bay. A few years later these were supplemented by measurements at the South Pole and elsewhere on the continent. Satellite measurements began in the early 70's, but the first really comprehensive satellite data came in 1978, with the TOMS (total ozone mapping spectrometer) and SBUV (solar backscatter UV) instruments on Nimbus-7. The Nimbus-7 TOMS, which finally broke down on 7 May 1993, is the source for most of the pretty pictures that one sees in review articles as well as the popular press. (See http://jwocky.gsfc.nasa.gov/). Today there are several satellites monitoring ozone and other atmospheric gases; instruments on NASA's UARS (Upper Atmosphere Research Satellite) simultaneously measure ozone, chlorine monoxide (ClO), and stratospheric pressure and temperature. ----------------------------- Subject: 6.) But I heard that Dobson saw an ozone hole in 1956-58... This is a myth, arising from a misinterpretation of an out-of- context quotation from a review article by Dobson. In his historical account [Dobson 1968b], Dobson mentioned that when springtime ozone levels over Halley Bay were first measured, he was surprised to find that they were about 150 DU below corresponding levels (displaced by six months) in the Arctic. Springtime arctic ozone levels are very high, ~450 DU; in the Antarctic spring, however, Dobson's coworkers found ~320 DU, close to winter levels. This was the first observation of the _normal_, pre-1980 behavior of the Antarctic ozone layer: because of the tight polar vortex (see below) ozone levels remain low until late spring. In the Antarctic ozone hole, on the other hand, ozone levels _decrease_ from these already low values. What Dobson describes is essentially the _baseline_ from which the ozone hole is measured. [Dobson 1968b] [WMO 1989] For those interested, here is how springtime antarctic ozone has developed from 1956 to 1995: .............................................................. Halley Bay Antarctic Ozone Data Mean October ozone column thickness, Dobson Units, as measured at the British Antarctic Survey station at Halley Bay (Latitude 76 south, Longitude 26 west) 1956 321 1971 299 1986 248 1957 330 1972 304 1987 163 1958 314 1973 289 1988 232 1959 311 1974 274 1989 164 1960 301 1975 308 1990 179 1961 317 1976 283 1991 155 1962 332 1977 251 1992 142 1963 309 1978 284 1993 111 1964 318 1979 261 1994 124 1965 281 1980 227 1995 129 1966 316 1981 237 1996 139 1967 323 1982 234 1997 139 1968 301 1983 210 1969 282 1984 201 1970 282 1985 196 Data from J. D. Shanklin, British Antarctic Survey, personal communications, 1993-95. For published graphs, see [Jones and Shanklin], [Hamill and Toon], [Solomon], or [WMO 1991], p. 4.6. The original Farman et al. figure, which includes the years 1957-84, is available on the web at http://www.atm.ch.cam.ac.uk/images/easoe/total_ozone.gif An updated version can be found on the British Antarctic Survey web site: http://www.nbs.ac.uk/public/icd/jds/ozone/ Bulletins showing daily ozone measurements at Halley Bay and at Faraday Station can also be obtained through this web site. ----------------------------- Subject: 7.) Why is the hole in the Antarctic? This was a mystery when the hole was first observed, but it is now well understood. I shall limit myself to a brief survey of the present theory, and refer the reader to two excellent nontechnical articles [Toon and Turco] [Hamill and Toon] for a more comprehensive discussion. Briefly, the unusual physics and chemistry of the Antarctic stratosphere allows the inactive chlorine "reservoir" compounds to be converted into ozone- destroying chlorine radicals. While there is no more chlorine over antarctica than anywhere else, in the antarctic spring most of the chlorine is in a form that can destroy ozone. The story takes place in six acts, some of them occurring simultaneously on parallel stages: a.) The Polar Vortex As the air in the antarctic stratosphere cools and descends during the winter, the Coriolis effect sets up a strong westerly circulation around the pole. When the sun returns in the spring the winds weaken, but the vortex remains stable until November. The air over antarctica is largely isolated from the rest of the atmosphere, forming a gigantic reaction vessel. The vortex is not circular, it has an oblong shape with the long axis extending out over Patagonia. For further information about the dynamics of the polar vortex see [Schoeberl and Hartmann], [Tuck 1989], [AASE], [Randel], [Plumb], and [Waugh]. For a rather short movie (mpeg format) illustrating it, go to http://daac.gsfc.nasa.gov/CAMPAIGN_DOCS/UARS_project.html. There is some controversy about just how isolated the air in the vortex is. Some believe that the vortex is better thought of as a flow reactor than as a containment vessel; ozone-rich air enters the vortex from above while ozone-poor and ClO-rich air is stripped off the sides. Recent tracer measurements lend some support to this view, but the issue is unresolved. See [Randel] and [Plumb]. b.) Polar Stratospheric Clouds ("PSC") The Polar vortex is extremely cold; temperatures in the lower stratosphere drop below -80 C. Under these conditions large numbers of clouds appear in the stratosphere. These clouds are composed largely of nitric acid and water, probably in the form of crystals of nitric acid trihydrate ("NAT"), HNO3.3(H2O). Stratospheric clouds also form from ordinary water ice (so-called "Type II PSC"), but these are much less common; the stratosphere is very dry and water-ice clouds only form at the lowest temperatures. c.) Reactions On Stratospheric Clouds Most of the chlorine in the stratosphere ends up in one of the reservoir compounds, Chlorine Nitrate (ClONO2) or Hydrogen Chloride (HCl). Laboratory experiments have shown, however, that these compounds, ordinarily inert in the stratosphere, do react on the surfaces of polar stratospheric cloud particles. HCl dissolves into the particles as they grow, and when a ClONO2 molecule becomes adsorbed the following reactions take place: ClONO2 + HCl -> Cl2 + HNO3 ClONO2 + H2O -> HOCl + HNO3 The Nitric acid, HNO3, stays in the cloud particle. In addition, stratospheric clouds catalyze the removal of Nitrogen Oxides ("NOx"), through the reactions: N2O5 + H2O -> 2 HNO3 N2O5 + HCl -> ClNO2 + HNO3 Since N2O5 is in (gas-phase) equilibrium with NO2: 2 N2O5 <-> 4 NO2 + O2 this has the effect of removing NO2 from the gas phase and sequestering it in the clouds in the form of nitric acid, a process called "denoxification" (removal of "NOx"). [Crutzen and Arnold] [Hamill and Toon] d.) Sedimentation and Denitrification The clouds may eventually grow big enough so that they settle out of the stratosphere, carrying the nitric acid with them ("denitrification"). Denitrification enhances denoxification. If, on the other hand, the cloud decomposes while in the stratosphere, nitrogen oxides are returned to the gas phase. Presumably this should be called "renoxification", but I have not heard anyone use this language :-). e.) Photolysis of active chlorine compounds The Cl2 and HOCl produced by the heterogeneous reactions are easily photolyzed, even in the antarctic winter when there is little UV present. The sun is always very low in the polar winter, so the light takes a long path through the atmosphere and the short-wave UV is selectively absorbed. Molecular chlorine, however, absorbs _visible_ and near-UV light: Cl2 + hv -> 2 Cl Cl + O3 -> ClO + O2 The effect is to produce large amounts of ClO. This ClO would ordinarily be captured by NO2 and returned to the ClONO2 reservoir, but "denoxification" and "denitrification" prevent this by removing NO2. f.) Catalytic destruction of ozone by active chlorine As discussed in Part I, Cl and ClO can form a catalytic cycle that efficiently destroys ozone. That cycle used free oxygen atoms, however, which are only abundant in the upper stratosphere; it cannot explain the ozone hole which forms in the lower stratosphere. Instead, the principal mechanism involves chlorine peroxide, ClOOCl (often referred to as the "ClO dimer") [Molina and Molina]: ClO + ClO -> ClOOCl ClOOCl + hv -> Cl + ClOO ClOO -> Cl + O2 2 Cl + 2 O3 -> 2 ClO + 2 O2 ------------------------------- Net: 2 O3 -> 3 O2 At polar stratospheric temperatures this sequence is extremely fast and it dominates the ozone-destruction process. The second step, photolysis of chlorine peroxide, requires UV light which only becomes abundant in the lower stratosphere in the spring. Thus one has a long buildup of ClO and ClOOCl during the winter, followed by massive ozone destruction in the spring. This mechanism is believed to be responsible for about 70% of the antarctic ozone loss. Another mechanism that has been identified involves chlorine and bromine [McElroy et al. 1986]: ClO + BrO -> Br + Cl + O2 Br + O3 -> BrO + O2 Cl + O3 -> ClO + O2 ----------------------- Net: 2 O3 -> 3 O2 This is believed to be responsible for ~20% of the antarctic ozone depletion. [Anderson et al.] Additional mechanisms have been suggested, but they seem to be less important. [WMO 1991] Since the reactions above photochemical steps, ozone depletion begins when sunlight returns to the vortex in late winter or early spring. Indeed, the hole forms "from the outside in": ozone destruction begins in midwinter at the outer edge of the vortex, and works its way in towards the pole as the sun gets higher. [Roscoe et al. 1997] The above description is highly schematic. For a thorough presentation, see [Solomon], [McElroy and Salawich], or [WMO 1989, 1991, 1994]. ----------------------------- Subject: 8.) What is the evidence for the present theory? The evidence is overwhelming - the results from a single 1987 expedition (albeit a crucial one) fill two entire issues of the Journal of Geophysical Research. What follows is a very sketchy summary; for more information the reader is directed to [Solomon] and to [Anderson et al.]. The theory described above (often called the "PSC theory") was developed during the years 1985-87. At the same time, others proposed completely different mechanisms, making no use of chlorine chemistry. The two most prominent alternative explanations were one that postulated large increases in nitrogen oxides arising from enhanced solar activity, and one that postulated an upwelling of ozone-poor air from the troposphere into the cold stratospheric vortex. Each hypothesis made definite predictions, and a program of measurements was carried out to test these. The solar activity hypothesis predicted enhanced levels of Nitrogen oxides (NOx), whereas the measurements show unusually _low_ NOx, in accordance with the PSC hypothesis. The "upwelling" hypothesis predicted upward air motion in the lower stratosphere, which is inconsistent with measurements of atmospheric tracers such as N2O which show that the motion is primarily downwards. Positive evidence for the PSC theory comes from ground-based and airborne observations of the various chlorine-containing compounds. These show that the reservoir species HCl and ClONO2 are extensively depleted in the antarctic winter and spring, while the concentration of the active, ozone-depleting species ClO is strongly enhanced. Measurements also show enormously enhanced concentrations of the molecule OClO. This is formed by a side-reaction in the BrO/ClO mechanism described above. Further evidence comes from laboratory studies. The gas-phase reactions have been reproduced in the laboratory, and shown to proceed at the rates required in order for them to be important in the polar stratosphere. [Molina et al. 1990] [Sander et al.] [Trolier et al.] [Anderson et al.]. The production of active chlorine from reservoir chlorine on ice and sulfuric acid surfaces has also been demonstrated in the laboratory [Tolbert et al. 1987,1988] [Molina et al. 1987]. (Recently evidence for these reactions has been found in the arctic stratosphere as well: air parcels that had passed through regions where the temperature was low enough to form PSC's were found to have anomalously low concentrations of HCl and anomalously high concentrations of ClO [AASE].) The "smoking gun" is usually considered to be the simultaneous in-situ measurements of a variety of trace gases from an ER-2 stratospheric aircraft (a converted U2 spy plane) in August-October 1987. [Tuck et al.] These measurements demonstrated a striking "anticorrelation" between local ozone concentrations and ClO concentrations. Upon entering the ozone hole, ClO concentrations suddenly jump by a factor of 20 or more, while ozone concentrations drop by more than 50%. Even local fluctuations in the concentrations of the two species are tightly correlated. [Anderson et al.] The correlation is quantitatively accurate: from the measured local ClO concentrations together with reaction rate constants measured in the laboratory, one can calculate ozone destruction rates which agree well with the measured ozone concentrations. In summary, the PSC theory explains the following observations: 1. The ozone hole occupies the region of the polar vortex where temperatures are below -80 C and where polar stratospheric clouds are abundant. 2. The ozone hole is confined to the lower stratosphere. 3. The ozone hole appears when sunlight illuminates the vortex, and disappears soon after temperatures rise past -80 C, destroying PSC's. 4. The hole is associated with extremely low concentrations of NOx. 5. The hole is associated with very low concentrations of the chlorine "reservoirs", HCl and ClONO2, and very high concentrations of active chlorine compounds, ClO, and of byproducts such as OClO. 6. Inside the hole, the concentrations of ClO and ozone are precisely anticorrelated, high ClO being accompanied by low ozone. The correlation is quantitatively accurate. 7. Laboratory experiments demonstrate that chlorine reservoir compounds do react to give active chlorine on the surfaces of ice particles. 8. Airborne measurements in the polar stratosphere show that air which has passed through regions containing PSC's is low in reservoir chlorine and high in active chlorine. The antarctic ozone hole, once a complete mystery, is now one of the best understood aspects of the entire subject; it is much better understood than the small but steadily growing ozone depletion at mid latitudes, for example. ----------------------------- Subject: 9.) Will the ozone hole keep growing? To answer this, we need to consider separately the lateral dimensions (the "area" of the hole), the vertical dimension (its "depth") and the temporal dimension (how long the hole lasts.) ----------------------------- Subject: a.) Lateral Extent Let us define the "hole" to be the region where the total ozone column is less than 200 DU, i.e. where total ozone has fallen to less than 2/3 of normal springtime antarctic values. Defined thus, the hole is always confined to the south polar vortex, south of ~55 degrees. At present it does not fill the whole vortex, only the central core where stratospheric temperatures are less than ~-80 C. Typically this region is south of ~65 degrees, although there is a great deal of variation - in some years the center of the vortex is displaced well away from the pole, and the nominal boundary of the hole has on a few occasions passed over the tip of Chile. If stratospheric chlorine continued to rise, the hole could fill the entire vortex, which could as much as double its area. [Schoeberl and Hartmann] [Schoeberl et al. 1996]. However, while stratospheric chlorine is still rising its rate of increase has slowed dramatically and it is expected to peak before the end of the century. In any case, it cannot grow beyond ~55 degrees without a major change in the antarctic wind patterns that would allow the vortex itself to grow. There is no reason to expect the hole to expand out over Australia, or South Africa, although these regions could experience further ozone depletion after the hole breaks up and the ozone-poor air drifts north. ----------------------------- Subject: b.) Vertical Depth The hole is confined to the lower stratosphere, where the clouds are abundant. In this region the ozone is essentially gone. The upper stratosphere is much less affected, however, so that overall column depletion comes to ~50%. As stratospheric chlorine concentrations continue to increase over the next 10 years or so, some penetration to higher altitudes may take place, but large increases in depth are not expected. (The sulfate aerosols from the eruption of Mt. Pinatubo in 1991 allowed the 1992 and 1993 holes to extend over a larger altitude range than usual, both higher and lower [Hofmann et al. 1994, 1995].) ----------------------------- Subject: c.) Duration of the hole Here we might see important effects. The hole is destroyed in late spring/early summer when the vortex breaks up and warm, ozone-rich air rushes in. If the stratosphere cools, the vortex becomes more stable and lasts longer. As mentioned above, the greenhouse effect actually cools the stratosphere. There is a more direct cooling mechanism, however - remember that the absorption of solar UV by ozone is the major source of heat in the stratosphere, and is the reason that the temperature of the stratosphere increases with altitude. Depletion of the ozone layer therefore cools the stratosphere, and in this sense the hole is self-stabilizing. [Jones and Shanklin] In future years we might see more long-lived holes like that in 1990, which survived into early December. Also, with more chlorine in the stratosphere the hole may open earlier in the season, as has happened between 1993 and 1996. (The relationship between ozone depletion and climate change is complicated; for an introduction see [WMO 1991].) ----------------------------- Subject: 10.) Why be concerned about an ozone hole over antarctica? Nobody lives down there. First of all, even though the ozone hole is confined to the antarctic, its effects are not. After the hole breaks up in the spring, ozone-poor air drifts north and mixes with the air there, resulting in a transient decrease at middle and high latitudes. This has been seen as far north as Australia [WMO 1991][Roy et al.] [Atkinson et al.] On a time scale of months short-wave UV regenerates the ozone, but it is believed that this "dilution" may be a major cause of the much smaller _global_ ozone depletion, ~3% per decade, that has been observed. Moreover, the air from the ozone hole is also rich in ClO and can destroy more ozone as it mixes with ozone-rich air. Even during the spring, the air in the vortex is not _completely_ isolated, although there is some controversy over the extent to which the ozone hole acts as a "chemical processor" for the earth's atmosphere. ([Tuck 1989] [Schoeberl and Hartmann] [AASE] [Randel] [Waugh].) From a broader standpoint, the ozone hole is a distant early warning message. Because of its unusual meteorological properties the antarctic stratosphere is especially sensitive to chemical perturbations; the natural mechanisms by which chlorine is sequestered in reservoirs fail when total stratospheric chlorine reaches about 2 parts per billion. This suggests that allowing CFC emissions to increase by 3% per year, as was occurring during the 1980's, is unwise, to say the least. The emission reduction schedules negotiated under the Montreal Protocol (as revised in 1990 and 1992) lead to a projected maximum of ~4 ppb total strat. chlorine in the first decade of the 21st century, followed by a gradual decrease. Letting emissions increase at 3%/year would have led to >16 ppb total stratospheric chlorine by 2040, and even a freeze at 1980 rates would have led to >10 ppb. [Prather et al.]. ----------------------------- Subject: 11.) Is there an ozone hole in the arctic? There is no _massive_ ozone loss in the arctic, although there _is_ unusually large springtime ozone depletion, so the word "hole" is not appropriate. I like the expression "arctic ozone dimple" but this is not canonical :-). The arctic polar vortex is much weaker than the antarctic, arctic temperatures are several degrees higher, and polar stratospheric clouds are less common and tend to break up earlier in the spring.) [Salby and Garcia] Thus even though wintertime ClO gets very high, as high as antarctic ClO in 1991-2, it does not remain high through the spring, when it counts. [AASE] Recent UARS measurements, however, indicate that in 1993 arctic stratosphere temperatures stayed low enough to retain PSC's until late February, and ClO remained high into March. Large ozone depletions, ~10-20%, were reported for high latitudes in the Northern Hemisphere; these still do not qualify as an "ozone hole" but they do seem to indicate that the same physics and chemistry are operating, albeit with much less efficiency. [Waters et al.] [Gleason et al.] Large ozone depletion was not seen in the spring of 1994, but appeared again in the spring of 1995 [Wirth and Renger 1996], and, according to preliminary reports, again in 1996 (WMO press release, 12 March 1996, http://www.wmo.ch/web/Press/Press586.html). If "global warming" does indeed take place during the first few decades of the next century, we may see a dramatic change in arctic ozone. The greenhouse effect warms the surface of the earth, but at the same time _cools_ the stratosphere. Since there is much less air in the stratosphere, 2-3 degrees of surface warming corresponds to a much larger decrease in stratospheric temperatures, as much as 10 degrees. This could lead to a true ozone hole in the arctic, although it would still probably be smaller and weaker than the antarctic hole. [Austin et al.] The 27 August issue of _Science_ magazine contains 8 papers devoted to arctic ozone depletion in the winter of 1991-92. [AASE] See also [von der Gathen et al. 1995], [Manney et al. 1994], and [Wirth and Renger 1996] who present evidence linking arctic ozone depletion to chlorine and bromine chemistry. ----------------------------- Subject: 12.) Can the hole be "plugged"? The present ozone hole, while serious, is not in itself catastrophic. UV radiation is always low in polar regions since the sun takes a long path through the atmosphere and hence through the ozone layer. There may be serious consequences for marine life in the antarctic ocean, which is adapted to the normally low UV levels. When the hole breaks up in summer, there may be temporary increases in UV-b at high latitudes of the southern hemisphere as air that is poor in ozone and rich in "active", ozone-destroying forms of chlorine mixes with the air outside. Nevertheless it looks like we are stuck with the hole for the next 50 years at least, and we don't know what new surprises the atmosphere has in store for us. Thus, some atmospheric scientists have been exploring the possibility of fixing the hole by technological means. All such schemes proposed so far are highly tentative, and there are no plans to carry any of them out until the chemistry and dynamics of the stratosphere are much better understood than they are at present. It should be made clear at the beginning that there is no point in trying to replace the ozone directly. The amounts are far too large to be transported to the stratosphere, and the antarctic mechanisms are so fiendishly efficient that they will easily destroy added ozone (recall that where the catalytic cycles operate, ~95% of the ozone is gone, in spite of the fact that the sun is generating it all the time.) It is far better to try to remove the halogen catalysts. One suggestion made a few years ago was to release sodium metal into the stratosphere, in hopes that it would form sodium chloride crystals which would settle out. The problem is that the microcrystals remain suspended as long as they are small, and can play the same role as clouds and aerosols in converting reservoir chlorine to active chlorine. A second suggestion is to destroy the CFC's while they are still in the troposphere, by photolyzing them with high-powered infrared lasers installed on mountainsides. (CFC's and similar molecules can absorb as many as 30 infrared photons from a single laser pulse, a phenomonon known as infrared multiphoton dissociation). The chlorine atoms released would quickly be converted to HCl and rained out. The power requirements of such a project are daunting, however, and it appears that much of the laser radiation would be shifted out of the desired frequency range by stimulated raman scattering. [Stix] A more serious possibility is being explored by one of the discoverers of chlorine-catalyzed ozone depletion, Ralph Cicerone, together with Scott Elliot and Richard Turco [Cicerone et al. 1991,1992]. They considered the effects of dumping ~50,000 tons of ethane or propane, several hundred planeloads, into the antarctic stratosphere every spring. The hydrocarbons would react rapidly with the Cl-containing radicals to give back the reservoir HCl. The hydrocarbons themselves are fairly reactive and would decompose by the end of a year, so the treatment would have to be repeated annually. The chlorine would not actually be removed from the stratosphere, but it would be bound up in an inert form - in other words, the catalyst would be "poisoned". There are no plans to carry this or any other scheme out in the near future; to quote from Cicerone et al. (1991), "Before any actual injection experiment is undertaken there are many scientific, technical, legal and ethical questions to be faced, not the least of which is the issue of unintended side effects." ----------------------------- Subject: REFERENCES FOR PART III A remark on references: they are neither representative nor comprehensive. There are _hundreds_ of people working on these problems. For the most part I have limited myself to papers that are (1) widely available (if possible, _Science_ or _Nature_ rather than archival sources such as _J. Geophys. Res._) and (2) directly related to the "frequently asked questions". This gives very short shrift to much important work; for example, I say very little about stratospheric NOx, even though a detailed accounting of chemistry and transport of the nitrogen oxides is one of the major goals of current research. Readers who want to see "who did what" should consult the review articles listed below, or, if they can get them, the extensively documented WMO reports. ----------------------------- Subject: Introductory Reading [Graedel and Crutzen] T. Graedel and P. Crutzen, _Atmospheric Change: an Earth System Perspective_, Freeman, 1993. [Hamill and Toon] P. Hamill and O. Toon, "Polar stratospheric clouds and the ozone hole", _Physics Today_ December 1991. [Stolarski] Richard Stolarski, "The Antarctic Ozone Hole", _Sci. American_ Jan. 1988. (this article is now seriously out of date, but it is still a good place to start). [Toon and Turco] O. Toon and R. Turco, "Polar Stratospheric Clouds and Ozone Depletion", _Sci. American_ June 1991 [Zurer] P. S. Zurer, "Ozone Depletion's Recurring Surprises Challenge Atmospheric Scientists", _Chemical and Engineering News_, 24 May 1993, pp. 9-18. ----------------------------- Subject: Books and Review Articles [Anderson, Toohey and Brune] J.G. Anderson, D. W. Toohey, and W. H. Brune, "Free Radicals within the Antarctic vortex: the role of CFC's in Antarctic Ozone Loss", _Science_ _251_, 39, 1991. [McElroy and Salawich] M. McElroy and R. Salawich, "Changing Composition of the Global Stratosphere", _Science_ _243, 763, 1989. [Solomon] S. Solomon, "Progress towards a quantitative understanding of Antarctic ozone depletion", _Nature_ _347_, 347, 1990. [Wayne] R. P. Wayne, _Chemistry of Atmospheres_, 2nd. Ed., Oxford, 1991, Ch. 4. [WMO 1988] World Meteorological Organization, _Report of the International Ozone Trends Panel_, Global Ozone Research and Monitoring Project - Report #18. [WMO 1989] World Meteorological Organization, _Scientific Assessment of Stratospheric Ozone: 1989_ Global Ozone Research and Monitoring Project - Report #20. [WMO 1991] World Meteorological Organization, _Scientific Assessment of Ozone Depletion: 1991_ Global Ozone Research and Monitoring Project - Report #25. [WMO 1994] World Meteorological Organization, _Scientific Assessment of Ozone Depletion: 1994_ Global Ozone Research and Monitoring Project - Report #37. ----------------------------- Subject: More Specialized References [AASE] Papers resulting from the Second Airborne Arctic Stratosphere Expedition, published in _Science_ _261_, 1128-1157, 27 Aug. 1993. [Atkinson et al.] R. J. Atkinson, W. A. Matthews, P. A. Newman, and R. A. Plumb, "Evidence of the mid-latitude impact of Antarctic ozone depletion", _Nature_ _340_, 290, 1989. [Austin et al.] J. Austin, N. Butchart, and K. P. Shine, "Possibility of an Arctic ozone hole in a doubled-CO2 climate", _Nature_ _360_, 221, 1992. [Cicerone et al. 1991] R. Cicerone, S. Elliot, and R. Turco, "Reduced Antarctic Ozone Depletions in a Model with Hydrocarbon Injections", _Science_ _254_, 1191, 1991. [Cicerone et al. 1992] R. Cicerone, S. Elliot, and R. Turco, "Global Environmental Engineering", _Nature_ _356_, 472, 1992. [Crutzen and Arnold] P. J. Crutzen and F. Arnold, "Nitric acid cloud formation in the cold Antarctic stratosphere: a major cause for the springtime 'ozone hole'", _Nature_ _324_, 651, 1986. [Dobson 1968a] G. M. B. Dobson, _Exploring the Atmosphere_, 2nd Edition, Oxford, 1968. [Dobson 1968b] G. M. B. Dobson, "Forty Years' research on atmospheric ozone at Oxford", _Applied Optics_, _7_, 387, 1968. [Farman et al.] J. C. Farman, B. G. Gardiner, and J. D. Shanklin, "Large losses of total ozone in Antarctica reveal seasonal ClOx/NOx interaction", _Nature_ _315_, 207, 1985. [Frederick and Alberts] J. Frederick and A. Alberts, "Prolonged enhancement in surface ultraviolet radiation during the Antarctic spring of 1990", _Geophys. Res. Lett._ _18_, 1869, 1991. [Gleason et al.] J. Gleason, P. Bhatia, J. Herman, R. McPeters, P. Newman, R. Stolarski, L. Flynn, G. Labow, D. Larko, C. Seftor, C. Wellemeyer, W. Komhyr, A. Miller, and W. Planet, "Record Low Global Ozone in 1992", _Science_ _260_, 523, 1993. [Hofmann et al. 1994] D. J. Hofmann, S. J. Oltmans, J. A. Lathrop, J. M. Harris, and H. Vomel, "Record low ozone at the South Pole in the Spring of 1993", _Geophys. Res. Lett._ _21_, 421, 1994. [Hofmann et al. 1995] D. J. Hofmann, S. J. Oltmans, B. J. Johnson, J. A. Lathrop, J. M. Harris, and H. Vomel, "Recovery of ozone in the lower stratosphere at the South Pole during the spring of 1994", _Geophys. Res. Lett._ _22_, 2493, 1995. [Jones and Shanklin] A. E. Jones and J. D. Shanklin, "Continued decline of total ozone over Halley, Antarctica, since 1985", _Nature__376_, 409, 1995. [Manney et al 1994] G. L. Manney, L. Froidevaux, J. W. Waters, R. W. Zurek, W. G. Read, L. S. Elson, J. B. Kumer, J. L. Mergenthaler, A. E. Roche, A. O'Neill, R. S. Harwood, I. MacKenzie, and R. Swinbank, "Chemical depletion of ozone in the Arctic lower stratosphere during winter 1992-93", _Nature_ _370_, 429, 1994. [McElroy et al. 1986] M. B. McElroy, R. J. Salawich, S. C. Wofsy, and J. A. Logan, "Antarctic ozone: reductions due to synergistic interactions of chlorine and bromine", _Nature_ _321_, 759, 1986. [McCormick et al. 1995] M. Patrick McCormick, L. W. Thomason, and C. R. Trepte, "Atmospheric effects of the Mt. Pinatubo eruption", _Nature_ _373_, 399, 1995. [Molina and Molina] L. T. Molina and M. J. Molina, "Production of Cl2O2 from the self-reaction of the ClO radical", J. Phys. Chem. _91_, 433, 1987. [Molina et al. 1987] M. J. Molina, T.-L. Tso, L. T. Molina, and F.C.-Y. Yang, "Antarctic stratospheric chemistry of chlorine nitrate, hydrogen chloride, and ice: Release of active chlorine", _Science_ _238_, 1253, 1987. [Molina et al. 1990] M. Molina, A. Colussi, L. Molina, R. Schindler, and T.-L. Tso, "Quantum yield of chlorine atom formation in the photodissociation of chlorine peroxide (ClOOCl) at 308 nm", _Chem. Phys. Lett._ _173_, 310, 1990. [Plumb] A. Plumb, "Mixing and Matching", _Nature_ _365_, 489-90, 1993. (News and Views column.) [Prather et al.] M. J. Prather, M. B. McElroy, and S. C. Wofsy, "Reductions in ozone at high concentrations of stratospheric halogens", _Nature_ _312_, 227, 1984. [Randel] W. Randel, "Ideas flow on Antarctic vortex", _Nature_ _364_, 105, 1993 (News and Views column) [Roscoe et al. 1997] H. K. Roscoe, A. E. Jones, A. M. Lee, "Midwinter Start to Antarctic Ozone Depletion: Evidence from Observations and Models", _Science_ _278_, 93 (1997). [Roy et al.] C. Roy, H. Gies, and G. Elliott, "Ozone Depletion", _Nature_ _347_, 235, 1990. (Scientific Correspondence) [Salby and Garcia] M. L. Salby and R. R. Garcia, "Dynamical Perturbations to the Ozone Layer", _Physics Today_ _43_, 38, March 1990. [Sander et al.] S.P. Sander, R.J. Friedl, and Y.K. Yung, "Role of the ClO dimer in polar stratospheric chemistry: rate of formation and implications for ozone loss", _Science_ _245_, 1095, 1989. [Schoeberl and Hartmann] M. Schoeberl and D. Hartmann, "The dynamics of the stratospheric polar vortex and its relation to springtime ozone depletions", _Science_ _251_, 46, 1991. [Schoeberl et al. 1996] M. R. Schoeberl, A. R. Douglass, S. R. Kawa, A. E. Dessler, P. A. Newman, R. S. Stolarski, A. E. Roche, J. W. Waters, and J. M. Russell III, "Development of the Antarctic ozone hole", J. Geophys. Res. _101_, 20909, 1996. [Solomon et al. 1993] S. Solomon, R. Sanders, R. Garcia, and J. Keys, "Increased chlorine dioxide over Antarctica caused by volcanic aerosols from Mt. Pinatubo", _Nature_ _363_, 245, 1993. [Stix] T. H. Stix, "Removal of Chlorofluorocarbons from the earth's atmosphere", _J. Appl. Physics_ _60_, 5622, 1989. [Stolarski et al. 1992] R. Stolarski, R. Bojkov, L. Bishop, C. Zerefos, J. Staehelin, and J. Zawodny, "Measured Trends in Stratospheric Ozone", Science _256_, 342 (17 April 1992) [Tolbert et al. 1987] M.A. Tolbert, M.J. Rossi, R. Malhotra, and D.M. Golden, "Reaction of chlorine nitrate with hydrogen chloride and water at Antarctic stratospheric temperatures", _Science_ _238_, 1258, 1987. [Tolbert et al. 1988] M.A. Tolbert, M.J. Rossi, and D.M. Golden, "Antarctic ozone depletion chemistry: reactions of N2O5 with H2O and HCl on ice surfaces", _Science_ _240_, 1018, 1988. [Tolbert 1994] M. A. Tolbert, "Sulfate Aerosols and Polar Stratospheric Cloud Formation", _Science_ _264_, 527, 1994. [Trolier et al.] M. Trolier, R.L. Mauldin III, and A. Ravishankara, "Rate coefficient for the termolecular channel of the self-reaction of ClO", _J. Phys. Chem._ _94_, 4896, 1990. [Tuck 1989] A. F. Tuck, "Synoptic and Chemical Evolution of the Antarctic Vortex in late winter and early spring, 1987: An ozone processor", J. Geophys. Res. _94_, 11687, 1989. [Tuck et al.] A. F. Tuck, R. T. Watson, E. P. Condon, and J. J. Margitan, "The planning and execution of ER-2 and DC-8 aircraft flights over Antarctica, August and September, 1987" J. Geophys. Res. _94_, 11182, 1989. [von der Gathen et al. 1995] P. von der Gathen, M. Rex, N. R. P. Harris, D. Lucic, B. M. Knudsen, G. O. Braathen, H. De Backer, R. Fabian, H. Fast, M. Gil, E. Kyro, I. S. Mikkelsen, M. Rummukainen, J. Staehelin, and C. Varotsos, "Observational evidence for chemical ozone depletion over the Arctic in winter 1991-92", _Nature_ _375_, 131, 1995. [Waters et al.] J. Waters, L. Froidevaux, W. Read, G. Manney, L. Elson, D. Flower, R. Jarnot, and R. Harwood, "Stratospheric ClO and ozone from the Microwave Limb Sounder on the Upper Atmosphere Research Satellite", _Nature_ _362_, 597, 1993. [Waugh] D. W. Waugh, "Subtropical stratospheric mixing linked to disturbances in the polar vortices", _Nature_ _365_, 535, 1993. [Wirth and Renger] M. Wirth and W. Renger, "Evidence of large scale ozone depletion within the arctic polar vortex 94/95 based on airbone LIDAR measurements", _Geophys. Res. Lett._ _23_, 813, 1996.