Standard

Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA. / Hocke, K.; Kämpfer, N.; Ruffieux, D.; Froidevaux, L.; Parrish, A.; Boyd, I.; Von Clarmann, T.; Steck, T.; Timofeyev, Y. M.; Polyakov, A. V.; Kyrölä, E.

в: Atmospheric Chemistry and Physics, Том 7, № 15, 01.01.2007, стр. 4117-4131.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Hocke, K, Kämpfer, N, Ruffieux, D, Froidevaux, L, Parrish, A, Boyd, I, Von Clarmann, T, Steck, T, Timofeyev, YM, Polyakov, AV & Kyrölä, E 2007, 'Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA', Atmospheric Chemistry and Physics, Том. 7, № 15, стр. 4117-4131. https://doi.org/10.5194/acp-7-4117-2007

APA

Hocke, K., Kämpfer, N., Ruffieux, D., Froidevaux, L., Parrish, A., Boyd, I., Von Clarmann, T., Steck, T., Timofeyev, Y. M., Polyakov, A. V., & Kyrölä, E. (2007). Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA. Atmospheric Chemistry and Physics, 7(15), 4117-4131. https://doi.org/10.5194/acp-7-4117-2007

Vancouver

Hocke K, Kämpfer N, Ruffieux D, Froidevaux L, Parrish A, Boyd I и пр. Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA. Atmospheric Chemistry and Physics. 2007 Янв. 1;7(15):4117-4131. https://doi.org/10.5194/acp-7-4117-2007

Author

Hocke, K. ; Kämpfer, N. ; Ruffieux, D. ; Froidevaux, L. ; Parrish, A. ; Boyd, I. ; Von Clarmann, T. ; Steck, T. ; Timofeyev, Y. M. ; Polyakov, A. V. ; Kyrölä, E. / Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA. в: Atmospheric Chemistry and Physics. 2007 ; Том 7, № 15. стр. 4117-4131.

BibTeX

@article{e955dd51710341509d4c0d19d21f1664,
title = "Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA",
abstract = "Stratospheric O3 profiles obtained by the satellite limb sounders Aura/MLS, ENVISAT/MIPAS, ENVISAT/GOMOS, SAGE-II, SAGE-III, UARS/HALOE are compared to coincident O3 profiles of the ground-based microwave radiometer SOMORA in Switzerland. Data from the various measurement techniques are within 10% at altitudes below 45 km. At altitudes 45-60 km, the relative O3 differences are within a range of 50%. Larger deviations at upper altitudes are attributed to larger relative measurement errors caused by lower O3 concentrations. The spatiotemporal characteristics of the O 3 differences (satellite ground station) are investigated by analyzing about 2300 coincident profile pairs of Aura/MLS (retrieval version 1.5) and SOMORA. The probability density function of the O3 differences is represented by a Gaussian normal distribution. The dependence of the O3 differences on the horizontal distance between the sounding volumes of Aura/MLS and SOMORA is derived. While the mean bias (Aura/MLS - SOMORA) is constant with increasing horizontal distance (up to 800 km), the standard deviation of the O3 differences increases from around 8 to 11% in the mid-stratosphere. Geographical maps yield azimuthal dependences and horizontal gradients of the O3 difference field around the SOMORA ground station. Coherent oscillations of O3 are present in the time series of Aura/MLS and SOMORA (e.g., due to traveling planetary waves). Ground- and space-based measurements often complement one another. We discuss the double differencing technique which allows both the cross-validation of two satellites by means of a ground station and the cross-validation of distant ground stations by means of one satellite. Temporal atmospheric noise in the geographical ozone map over Payerne is significantly reduced by combination of the data from SOMORA and Aura/MLS. These analyses illustrate the synergy of ground-based and space-based measurements.",
author = "K. Hocke and N. K{\"a}mpfer and D. Ruffieux and L. Froidevaux and A. Parrish and I. Boyd and {Von Clarmann}, T. and T. Steck and Timofeyev, {Y. M.} and Polyakov, {A. V.} and E. Kyr{\"o}l{\"a}",
year = "2007",
month = jan,
day = "1",
doi = "10.5194/acp-7-4117-2007",
language = "English",
volume = "7",
pages = "4117--4131",
journal = "Atmospheric Chemistry and Physics",
issn = "1680-7316",
publisher = "Copernicus GmbH ",
number = "15",

}

RIS

TY - JOUR

T1 - Comparison and synergy of stratospheric ozone measurements by satellite limb sounders and the ground-based microwave radiometer SOMORA

AU - Hocke, K.

AU - Kämpfer, N.

AU - Ruffieux, D.

AU - Froidevaux, L.

AU - Parrish, A.

AU - Boyd, I.

AU - Von Clarmann, T.

AU - Steck, T.

AU - Timofeyev, Y. M.

AU - Polyakov, A. V.

AU - Kyrölä, E.

PY - 2007/1/1

Y1 - 2007/1/1

N2 - Stratospheric O3 profiles obtained by the satellite limb sounders Aura/MLS, ENVISAT/MIPAS, ENVISAT/GOMOS, SAGE-II, SAGE-III, UARS/HALOE are compared to coincident O3 profiles of the ground-based microwave radiometer SOMORA in Switzerland. Data from the various measurement techniques are within 10% at altitudes below 45 km. At altitudes 45-60 km, the relative O3 differences are within a range of 50%. Larger deviations at upper altitudes are attributed to larger relative measurement errors caused by lower O3 concentrations. The spatiotemporal characteristics of the O 3 differences (satellite ground station) are investigated by analyzing about 2300 coincident profile pairs of Aura/MLS (retrieval version 1.5) and SOMORA. The probability density function of the O3 differences is represented by a Gaussian normal distribution. The dependence of the O3 differences on the horizontal distance between the sounding volumes of Aura/MLS and SOMORA is derived. While the mean bias (Aura/MLS - SOMORA) is constant with increasing horizontal distance (up to 800 km), the standard deviation of the O3 differences increases from around 8 to 11% in the mid-stratosphere. Geographical maps yield azimuthal dependences and horizontal gradients of the O3 difference field around the SOMORA ground station. Coherent oscillations of O3 are present in the time series of Aura/MLS and SOMORA (e.g., due to traveling planetary waves). Ground- and space-based measurements often complement one another. We discuss the double differencing technique which allows both the cross-validation of two satellites by means of a ground station and the cross-validation of distant ground stations by means of one satellite. Temporal atmospheric noise in the geographical ozone map over Payerne is significantly reduced by combination of the data from SOMORA and Aura/MLS. These analyses illustrate the synergy of ground-based and space-based measurements.

AB - Stratospheric O3 profiles obtained by the satellite limb sounders Aura/MLS, ENVISAT/MIPAS, ENVISAT/GOMOS, SAGE-II, SAGE-III, UARS/HALOE are compared to coincident O3 profiles of the ground-based microwave radiometer SOMORA in Switzerland. Data from the various measurement techniques are within 10% at altitudes below 45 km. At altitudes 45-60 km, the relative O3 differences are within a range of 50%. Larger deviations at upper altitudes are attributed to larger relative measurement errors caused by lower O3 concentrations. The spatiotemporal characteristics of the O 3 differences (satellite ground station) are investigated by analyzing about 2300 coincident profile pairs of Aura/MLS (retrieval version 1.5) and SOMORA. The probability density function of the O3 differences is represented by a Gaussian normal distribution. The dependence of the O3 differences on the horizontal distance between the sounding volumes of Aura/MLS and SOMORA is derived. While the mean bias (Aura/MLS - SOMORA) is constant with increasing horizontal distance (up to 800 km), the standard deviation of the O3 differences increases from around 8 to 11% in the mid-stratosphere. Geographical maps yield azimuthal dependences and horizontal gradients of the O3 difference field around the SOMORA ground station. Coherent oscillations of O3 are present in the time series of Aura/MLS and SOMORA (e.g., due to traveling planetary waves). Ground- and space-based measurements often complement one another. We discuss the double differencing technique which allows both the cross-validation of two satellites by means of a ground station and the cross-validation of distant ground stations by means of one satellite. Temporal atmospheric noise in the geographical ozone map over Payerne is significantly reduced by combination of the data from SOMORA and Aura/MLS. These analyses illustrate the synergy of ground-based and space-based measurements.

UR - http://www.scopus.com/inward/record.url?scp=34547678157&partnerID=8YFLogxK

U2 - 10.5194/acp-7-4117-2007

DO - 10.5194/acp-7-4117-2007

M3 - Article

AN - SCOPUS:34547678157

VL - 7

SP - 4117

EP - 4131

JO - Atmospheric Chemistry and Physics

JF - Atmospheric Chemistry and Physics

SN - 1680-7316

IS - 15

ER -

ID: 36221265