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Observational evidence for chemical ozone depletion over the Arctic in winter 1991-92

Von der Gathen, Peter ; Rex, Markus ; Harris, Neil R.P. ; Lucic, Diana ; Knudsen, Bjørn M. ; Braathen, Geir O. ; De Backer, Hugo ; Fabian, Rolf ; Fast, Hans and Gil, Manuel , et al. (1995) In Nature 375(6527). p.131-134
Abstract

LONG-TERM depletion of ozone has been observed since the early 1980s in the Antarctic polar vortex, and more recently at mid-latitudes in both hemispheres, with most of the ozone loss occurring in the lower stratosphere1. Insufficient measurements of ozone exist, however, to determine decadal trends in ozone concentration in the Arctic winter. Several studies of ozone concentrations in the Arctic vortex have inferred that chemical ozone loss has occurred2-11; but because natural variations in ozone concentration at any given location can be large, deducing long-term trends from time series is fraught with difficulties. The approaches used previously have often been indirect, typically relying on relationships... (More)

LONG-TERM depletion of ozone has been observed since the early 1980s in the Antarctic polar vortex, and more recently at mid-latitudes in both hemispheres, with most of the ozone loss occurring in the lower stratosphere1. Insufficient measurements of ozone exist, however, to determine decadal trends in ozone concentration in the Arctic winter. Several studies of ozone concentrations in the Arctic vortex have inferred that chemical ozone loss has occurred2-11; but because natural variations in ozone concentration at any given location can be large, deducing long-term trends from time series is fraught with difficulties. The approaches used previously have often been indirect, typically relying on relationships between ozone and long-lived tracers. Most recently Manney et al.11used such an approach, based on satellite measurements, to conclude that the observed ozone decrease of about 20% in the lower stratosphere in February and March 1993 was caused by chemical, rather than dynamical, processes. Here we report the results of a new approach to calculate chemical ozone destruction rates that allows us to compare ozone concentrations in specific air parcels at different times, thus avoiding the need to make assumptions about ozone/tracer ratios. For the Arctic vortex of the 1991-92 winter we find that, at 20 km altitude, chemical ozone loss occurred only between early January and mid February and that the loss is proportional to the exposure to sunlight. The timing and magnitude are broadly consistent with existing understanding of photochemical ozone-depletion processes.

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type
Contribution to journal
publication status
published
in
Nature
volume
375
issue
6527
pages
4 pages
publisher
Nature Publishing Group
external identifiers
  • scopus:0028974469
ISSN
0028-0836
DOI
10.1038/375131a0
language
English
LU publication?
no
id
7d5ff4a8-bd11-4f28-9d40-d67204650e99
date added to LUP
2025-09-30 18:57:45
date last changed
2025-10-01 11:57:02
@article{7d5ff4a8-bd11-4f28-9d40-d67204650e99,
  abstract     = {{<p>LONG-TERM depletion of ozone has been observed since the early 1980s in the Antarctic polar vortex, and more recently at mid-latitudes in both hemispheres, with most of the ozone loss occurring in the lower stratosphere<sup>1</sup>. Insufficient measurements of ozone exist, however, to determine decadal trends in ozone concentration in the Arctic winter. Several studies of ozone concentrations in the Arctic vortex have inferred that chemical ozone loss has occurred<sup>2-11</sup>; but because natural variations in ozone concentration at any given location can be large, deducing long-term trends from time series is fraught with difficulties. The approaches used previously have often been indirect, typically relying on relationships between ozone and long-lived tracers. Most recently Manney et al.<sup>11</sup>used such an approach, based on satellite measurements, to conclude that the observed ozone decrease of about 20% in the lower stratosphere in February and March 1993 was caused by chemical, rather than dynamical, processes. Here we report the results of a new approach to calculate chemical ozone destruction rates that allows us to compare ozone concentrations in specific air parcels at different times, thus avoiding the need to make assumptions about ozone/tracer ratios. For the Arctic vortex of the 1991-92 winter we find that, at 20 km altitude, chemical ozone loss occurred only between early January and mid February and that the loss is proportional to the exposure to sunlight. The timing and magnitude are broadly consistent with existing understanding of photochemical ozone-depletion processes.</p>}},
  author       = {{Von der Gathen, Peter and Rex, Markus and Harris, Neil R.P. and Lucic, Diana and Knudsen, Bjørn M. and Braathen, Geir O. and De Backer, Hugo and Fabian, Rolf and Fast, Hans and Gil, Manuel and Kyrö, Esko and Mikkelsen, Ib Steen and Rummukainen, Markku and Stähelin, Johannes and Varotsos, Costas}},
  issn         = {{0028-0836}},
  language     = {{eng}},
  month        = {{05}},
  number       = {{6527}},
  pages        = {{131--134}},
  publisher    = {{Nature Publishing Group}},
  series       = {{Nature}},
  title        = {{Observational evidence for chemical ozone depletion over the Arctic in winter 1991-92}},
  url          = {{http://dx.doi.org/10.1038/375131a0}},
  doi          = {{10.1038/375131a0}},
  volume       = {{375}},
  year         = {{1995}},
}