An assessment of the ozone loss during the 1999–2000 SOLVE/THESEO 2000 Arctic campaign

Schoeberl, M. R.; Newman, Paul A.; Lait, Leslie R.; McGee, Thomas J.; Burris, J.; Browell, Edward V.; Grant, William B.; Richard, E. C.; Gathen, Peter von der; Bevilacqua, R. M.; Mikkelsen, I. S.

doi:10.1029/2001jd000412

Cited by 28 publications

(48 citation statements)

References 37 publications

(48 reference statements)

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“…Trajectories of up to 14 days can be included in Match analyses with no apparent negative impact on the ozone loss rate calculations. This result is consistent with the methodology of Schoeberl et al (2002), which uses a continuous data injection/trajectory approach with trajectories of up to 90 days duration and found a loss rate of 1.63±0.3 ppbv between 20 January and 12 March 1992. (Note that here and throughout this summary, quoted statistical uncertainties are at the one standard deviation level.…”

Section: Discussionsupporting

confidence: 90%

“…Published ozone loss rates calculated using Match for cold Arctic Januaries are generally about 30% larger than can be explained by our current understanding of polar stratospheric chemistry, with one to two individual data points in January 1992 that exceed model values by more than a factor of two (Becker et al, 1998). Schoeberl et al (2002) introduce a variant on the Match technique that uses many sources of data (sonde, satellite and aircraft) to initialize air parcel trajectories. By comparing new observations with the ozone values associated with the older, advected air parcels, chemical ozone loss again can be inferred.…”

Section: Introductionmentioning

confidence: 99%

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A review of the Match technique as applied to AASE-2/EASOE and SOLVE/THESEO 2000

et al. 2005

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Abstract. We apply the NASA Goddard Trajectory Model to data from a series of ozonesondes to derive ozone loss rates in the lower stratosphere for the AASE-2/EASOE mission (January-March 1992) and for the SOLVE/THESEO 2000 mission (January-March 2000) in an approach similar to Match. Ozone loss rates are computed by comparing the ozone concentrations provided by ozonesondes launched at the beginning and end of the trajectories connecting the launches. We investigate the sensitivity of the Match results to the various parameters used to reject potential matches in the original Match technique. While these filters effectively eliminate from consideration 80% of the matched sonde pairs and >99% of matched observations in our study, we conclude that only a filter based on potential vorticity changes along the calculated back trajectories seems warranted. Our study also demonstrates that the ozone loss rates estimated in Match can vary by up to a factor of two depending upon the precise trajectory paths calculated for each trajectory. As a result, the statistical uncertainties published with previous Match results might need to be augmented by an additional systematic error. The sensitivity to the trajectory path is particularly pronounced in the month of January, for which the largest ozone loss rate discrepancies between photochemical models and Match are found. For most of the two study periods, our ozone loss rates agree with those previously published. Notable exceptions are found for January 1992 at 475 K and late February/early March 2000 at 450 K, both periods during which we generally find smaller loss rates than the previous Match studies. Integrated ozone loss rates estimated by Match in both of those years compare well with those found in numerous other studies and in a potential vorticity/potential temperature approach shown previously and in this paper. Finally, we suggest an alternate approach to Match using trajectory mapping. This approach uses inforCorrespondence to: G. A. Morris (gary.morris@valpo.edu) mation from all matched observations without filtering and uses a two-parameter fit to the data to produce robust ozone loss rate estimates. As compared to loss rates from our version of Match, the trajectory mapping approach produces generally smaller loss rates, frequently not statistically significantly different from zero, calling into question the efficacy of the Match approach.

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Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

A review of the Match technique as applied to AASE-2/EASOE and SOLVE/THESEO 2000

et al. 2005

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“…However simple comparisons with the other studies in the 1999/2000 winter Klein et al, 2002;Müller et al, 2003 and discussion therein;Richard et al, 2001;Salawitch et al, 2002;Schoeberl et al, 2002;summary in Table 8 of Newman et al, 2002) show good agreement. We find that the peak loss occurred in the 440-470 K region, which is the same as Müller et al (2003), at the low end of the range.…”

Section: Discussionsupporting

confidence: 70%

Ozone loss derived from balloon-borne tracer measurements in the 1999/2000 Arctic winter

et al. 2005

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Abstract. Balloon-borne measurements of CFC11 (from the DIRAC in situ gas chromatograph and the DESCARTES grab sampler), ClO and O 3 were made during the 1999/2000 Arctic winter as part of the SOLVE-THESEO 2000 campaign, based in Kiruna (Sweden). Here we present the CFC-11 data from nine flights and compare them first with data from other instruments which flew during the campaign and then with the vertical distributions calculated by the SLIM-CAT 3D CTM. We calculate ozone loss inside the Arctic vortex between late January and early March using the relation between CFC11 and O 3 measured on the flights. The peak ozone loss (∼1200 ppbv) occurs in the 440-470 K region in early March in reasonable agreement with other published empirical estimates. There is also a good agreement between ozone losses derived from three balloon tracer data sets used here. The magnitude and vertical distribution of the loss derived from the measurements is in good agreement with the loss calculated from SLIMCAT over Kiruna for the same days.

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“… Hoppel et al [2002] find the maximum O 3 loss at ≈470 or 480 K depending on the passive O 3 employed (that is effectively depending on the heating rate calculation used). Schoeberl et al [2002] report ≈465 and 475 K as the altitude of maximum O 3 loss depending on whether POAM or sonde measurements are used as the O 3 data set. The altitude of maximum O 3 loss on 15 March 2000 obtained with the Match technique is 460 K [ Rex et al , 2002; Hoppel et al , 2002].…”

Section: Discussionmentioning

confidence: 99%

Chlorine activation and chemical ozone loss deduced from HALOE and balloon measurements in the Arctic during the winter of 1999–2000

et al. 2002

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We employ Halogen Occultation Experiment (HALOE) observations and balloon‐borne measurements (on the large Observations of the Middle Stratosphere [OMS] and Triple balloons, as well as on two small balloons) to investigate ozone loss in the stratospheric vortex in the 1999–2000 Arctic winter. Using HF and CH4 as long‐lived tracers, we identify chlorine activation and chemical ozone destruction in the polar vortex. Reference relations, representative of chemically undisturbed “early vortex” conditions, are derived from the OMS remote and in situ balloon measurements on 19 November and 3 December 1999, respectively. Deviations from this “early vortex” reference are interpreted as chemical ozone loss and heterogeneous chlorine activation. The observations show an extensive activation of chlorine; in late February 2000, the activation extends to altitudes of 600 K. Between 360 and 450 K chlorine was almost completely activated. At that time, about 70% of the HCl column between 380 and 550 K was converted to active chlorine. Furthermore, the measurements indicate severe chemical ozone loss, with a maximum loss of over 60% in the lower stratosphere (415–465 K) by mid‐March 2000. Substantial ozone loss was still observable in vortex remnants in late April 2000 (80 ± 10 Dobson units [DU] between 380 and 550 K). The average loss in column ozone between 380 and 550 K, inside the vortex core, in mid‐March amounted to 84 ± 13 DU.

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An assessment of the ozone loss during the 1999–2000 SOLVE/THESEO 2000 Arctic campaign

Cited by 28 publications

References 37 publications

A review of the Match technique as applied to AASE-2/EASOE and SOLVE/THESEO 2000

A review of the Match technique as applied to AASE-2/EASOE and SOLVE/THESEO 2000

Ozone loss derived from balloon-borne tracer measurements in the 1999/2000 Arctic winter

Chlorine activation and chemical ozone loss deduced from HALOE and balloon measurements in the Arctic during the winter of 1999–2000

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