The Scientific Assessment of Ozone Depletion is a sequence of reports sponsored by

WMO The World Meteorological Organization (WMO) is a specialized agency of the United Nations responsible for promoting international cooperation on atmospheric science, climatology, hydrology and geophysics. The WMO originated from the Internatio ...

UNEP The United Nations Environment Programme (UNEP) is responsible for coordinating responses to environmental issues within the United Nations system. It was established by Maurice Strong, its first director, after the United Nations Conference on ...

. The most recent report is from 2018. The reports were set up to inform the

Montreal Protocol The Montreal Protocol is an international treaty designed to protect the ozone layer by phasing out the production of numerous substances that are responsible for ozone depletion. It was agreed on 16 September 1987, and entered into force ...

and amendments about

ozone depletion Ozone depletion consists of two related events observed since the late 1970s: a steady lowering of about four percent in the total amount of ozone in Earth's atmosphere, and a much larger springtime decrease in stratospheric ozone (the ozone lay ...

Background

The Montreal and Vienna conventions were installed long before a scientific consensus was established.''Technische Problemlösung, Verhandeln und umfassende Problemlösun''g, (eng. technical trouble shooting, negotiating and generic problem solving capability)
in Gesellschaftliche Komplexität und kollektive Handlungsfähigkeit (Societys complexity and collective ability to act), ed. Schimank, U. (2000). Frankfurt/Main: Campus, p.154-18
book summary at the Max Planck Gesellschaft
/ref> Until the 1980s, EU, NASA, NAS, UNEP, WMO and the British government had all issued further different scientific reports with dissenting conclusions. Sir Robert (Bob) Watson, Director of the Science Division of at

National Aeronautics and Space Administration The National Aeronautics and Space Administration (NASA ) is an independent agency of the US federal government responsible for the civil space program, aeronautics research, and space research. NASA was established in 1958, succeeding ...

(NASA), played a crucial role in achieving unified reporting. The IPCC started from scratch with a more unified approach.

Findings

Changes in Ozone-Depleting Compounds

* In the

troposphere The troposphere is the first and lowest layer of the atmosphere of the Earth, and contains 75% of the total mass of the planetary atmosphere, 99% of the total mass of water vapour and aerosols, and is where most weather phenomena occur. Fro ...

observations show that the total abundance of ozone-depleting compounds continues to decline slowly from the peak that occurred in 1992-1994. * Observations in the

stratosphere The stratosphere () is the second layer of the atmosphere of the Earth, located above the troposphere and below the mesosphere. The stratosphere is an atmospheric layer composed of stratified temperature layers, with the warm layers of air h ...

indicate that the total chlorine abundance is at or near a peak, while bromine abundances are probably still increasing. * Analyses of air trapped in snow since the late 19th century have confirmed that non-industrial sources of the CFCs, halons, and major chlorocarbons were insignificant. The data suggest that substantial natural sources exist for atmospheric

methyl bromide Bromomethane, commonly known as methyl bromide, is an organobromine compound with formula C H3 Br. This colorless, odorless, nonflammable gas is produced both industrially and biologically. It has a tetrahedral shape and it is a recognized ozo ...

(CH₃Br). * The abundances of HCFCs in the

continue to increase. * water vapour is a greenhouse gas that has a greater overall effect on the ozone layer than carbon dioxide because of its higher concentrations but is not affected by human activities as it is caused mainly by evaporation and condensation rates.

Changes in the Ozone Layer over the Poles and Globally

* Springtime Antarctic ozone depletion due to halogens has been large (40-50%; exceptionally 70%) throughout the last decade. * In some recent cold Arctic winters during the last decade, maximum total column ozone losses due to halogens have reached 30%, but in warmer winters Arctic ozone loss is small. * Ozone remains depleted in the midlatitudes of both hemispheres. The global-average total column ozone amount for the period 1997-2001 was approximately 3% below the pre-1980 average values. * Models capture the observed long-term ozone changes in northern and southern midlatitudes.

Predictions

* Chemistry-climate models predict that springtime Antarctic ozone levels will be increasing by 2010 because of projected decreases of halogens in the stratosphere. A return to pre-1980 total column ozone amounts in the Antarctic is expected by the middle of this century. * Arctic ozone depletion is highly variable and difficult to predict, but a future Arctic polar ozone hole similar to that of the Antarctic appears unlikely.

Changes in Ultraviolet Radiation

* Decreases in ozone amounts lead to increases in UV radiation. Calculations of UV irradiance based on relationships with total ozone and total irradiance suggest that UV irradiance has increased since the early 1980s by 6-14% at more than 10 sites distributed over mid- and high latitudes of both hemispheres. But complexities (e.g. clouds, aerosol, snow cover, sea ice cover, and total ozone) limit the ability to describe fully surface ultraviolet radiation on the global scale. Surface ultraviolet data records, which started in the early 1990s, are still too short and too variable to permit the calculation of statistically significant long-term (i.e., multidecadal) trends. * However, estimates of surface UV radiation from satellite data (ozone and cloud cover) started in November 1978 with the launch of Nimbus-7/TOMS (Total Ozone Mapping Spectrometer) followed by Meteor-3/TOMS in 1991, Earth-Probe/TOMS in 1996, and by OMI (Ozone Measuring Instrument on the EOS/AURA spacecraft) in July 2004. These time series are sufficient for estimates of multidecade trends in ozone, cloud cover, and UV irradiance. The results clearly show that there have been significant increases in surface UVB at latitudes greater than about 40 degrees (northern US and Canada, most of Europe, Russia, and the southernmost portions of Argentina and Chile). The percent increase depends on the wavelength, with shorter wavelengths showing a larger percent increase. * Exposure to UV irradiance reaching the Earth's surface is also affected by the amount of cloud cover and by the altitude above sea level. These factors affect both UVA and UVB in nearly the same manner (less cloud cover or higher altitudes increase UV radiation at the Earth's surface). Some countries, such as Australia, have much less cloud cover than comparable sites in the Northern Hemisphere, and have much greater daily exposure to UV radiation. Australia, in particular, is known for health effects associated with UV exposure, and has a vigorous public health program to combat this problem. Satellite reflectivity data (TOMS) suggests that some populated regions (e.g., central Europe) have experienced small decreases in cloudiness, which would contribute to overall UV increases.

Reports

Scientific Assessment of Ozone Depletion: 2002

WMO/UNEP Scientific Assessment of Ozone Depletion: 1998

WMO/UNEP Scientific Assessment of Ozone Depletion: 1994
* Scientific Assessment of Ozone Depletion: 1991. WMO No. 25. * Scientific Assessment of Stratospheric Ozone: 1989. 2 vol. WMO No. 20. * (International Ozone Trends Panel Report 1988. 2 vol. WMO No. 18.) * (Atmospheric Ozone 1985. 3 vol. WMO No. 16.) * (The Stratosphere 1981 Theory and Measurements. WMO No. 11.) (The bracketed 1988, 1985 and 1981 papers are precursor reports relevant to the

but not directly part of this series).

References

{{Reflist Ozone depletion