The Ozone ‘Hole’

The Antarctic ozone ‘hole’ is caused by a springtime thinning of the ozone layer between particular altitudes over Antarctica. Such thinning has been detected each year for the past decade. Formation of the ‘hole’ occurs each September and recovery to ‘normal’ conditions occurs in late spring or early summer.

In October 1987,1989,1990 and 1991, deep ozone holes were observed over Antarctica with up to 60% less ozone compared to pre-ozone hole levels. In October 1991, the lowest levels of atmospheric ozone ever recorded occurred over Antarctica.      

There appear to be two major reasons for the ‘hole’ – the worldwide observed increases of CFCs detected throughout the atmosphere, and the unique wintertime meteorological environment over Antarctica. Between particular altitudes above Antarctica, the very cold stratospheric temperatures allow ice crystals clouds to form.

In these clouds, chlorine molecules from CFCs are chemically released during the darkness of the polar winter. The resultant build-up of chlorine molecules is reduced to ozone-destroying chlorine atoms by the action of UV when sunlight begins in September over Antarctica.

Global Ozone Decline

Ground-based and satellite measurements show significant decreases of total column ozone in winter and summer for both northern and southern hemispheres at middle and high latitudes. These downward trends were larger during the 1980s than in the 1970s. No statistically significant trends have been determined for the tropics during the 1980s. The most advanced computer models of global chemical destruction of stratospheric ozone explain most of the observed trend of total ozone in middle latitudes in summer, but only about half of that in winter. This means that future global ozone changes cannot be satisfactorily predicted as yet.

Measurement of Ozone

Total ozone is measured in several ways:

Satellites

The use of polar-orbiting satellites such as the Nimbus7 NASA Satellite carrying the Total Ozone Mapping Spectrometer (TOMS) instruments has revolutionized ozone monitoring over the past 20 years. Their high vantage point in space, and the ability of each satellite to traverse the entire globe, provides a much better coverage than ground stations. This is invaluable in determining global trends. The most accurate satellite sensors use the same principles as the Dobson spectrophotometer.

Dobson spectrophotometer

The first spectrophotometer was built in the 1920s by Gordon Dobson for the purpose of measuring total ozone. Today about 80 of these types of instruments are used worldwide for measurement of total ozone. The Dobson spectrophotometer measures ozone by comparing the amount of sunlight at two ultraviolet lengths. One wavelength is strongly affected by ozone; the other is not. The difference between the two sunlight amounts is directly related to the total ozone.

Ozone sonde

An ozone sonde is an electrochemical cell and radio transmitter attached to a hydrogen-filled balloon that can reach a height of about 35 km. Air is drawn into small cell by a pump. The solution in the cell reacts with ozone, producing a small electric current that is directly proportional to the ozone amount. The signal from the cell is converted into a code and transmitted via radio to a receiving station. From the launch of the balloon until its failure, typically at about 35 km, the sonde provides a vertical distribution of ozone.

World Action

In 1975, following concern that human activities may threaten the ozone layer, the WMO, at the request of the United Nations Environment Programme (UNEP) initiated the Global Ozone Research and Monitoring Project to coordinate the long-term monitoring and research of ozone.

All data from monitoring sites all over the world are transmitted to the World Ozone Data Center in Toronto, Canada, where they are available to the international scientific community.  

In 1977 a UNEP meeting of experts adopted the World Plan of Action on the Ozone Layer; in 1987 UNEP adopted the Montreal Protocol on Substances that Deplete the Ozone Layer.

World-wide network of total ozone stations

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