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2. Feasibility Cues during a Sexual Encounter Impact the Strength of Heterosexual Women's Orgasm Goal Pursuit.

Author

Wetzel, G. M., Sanchez, D. T., and Cole, S.

Subjects
*ORGASM, *SEXUAL excitement, *SEXUAL intercourse, *HETEROSEXUAL women, *SEXUAL partners, *SELF regulation
Abstract

The "orgasm gap" for women who have sex with men remains a pressing gender equity issue. Recent research found that women who pursued orgasm as a goal were more likely to have one. The current research replicated this relationship between orgasm goal pursuit and orgasm frequency for heterosexual women, and found that this relationship did not exist for heterosexual men (Study 1). Then, across two experimental studies, we examined how heterosexual women vary their orgasm goal pursuit across sexual encounters. In Study 2, women who read that a hypothetical sexual encounter would be "quick" reported less intent to pursue orgasm than women who were told they could "take their time" or received no time information. In Study 3, women who read that their hypothetical sexual partner seemed selfish reported less intent to pursue orgasm than women who were given a non-selfish partner or no partner information. Importantly, these effects were mediated by women's perceived orgasm likelihood in the scenario. These results suggest that women shift their pursuit of orgasm depending on cues which signal whether orgasm will be feasible. This research used self-regulation theory to understand women's motivations for pursuing orgasm during sexual encounters with men, with implications for reducing the orgasm gap. [ABSTRACT FROM AUTHOR]

Published
2024
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8. ESA Version 8 reprocessing of the 10 years of MIPAS on ENVISAT measurements

Author

Raspollini, Piera, Barbara, Flavio, Bianchini, M., Birk, Manfred, Ceccherini, Simone, Dehn, Angelika, Dudhia, Anu, Dinelli, Bianca Maria, Flaud, J.-M., Gai, Marco, Hoepfner, Michael, Daan, Hubert, Keppens, Arno, Kiefer, Michael, Kleinert, A., Moore, D., Papandrea, E., Perron, Gaétan, Piro, A., López-Puertas, Manuel, Oelhaf, H., Pettinari, Paolo, Remedios, J., Ridolfi, Marco, Sgheri, Luca, Wagner, Georg, Wetzel, G., and Zoppetti, Nicole

Subjects
L1 processing, MIPAS, MIPAS/ENVISAT, satellite remote sensing, Atmospheric composition, Fourier-transform spectroscopy, Level 2 data quality, L2 Processing, atmospheric trace gases
Abstract

MIPAS is a Fourier Transform spectrometer that measured the atmospheric limb emission spectra in the middle infrared on board the ENVISAT satellite. These measurements allowed the global monitoring of the three-dimensional (latitude, longitude and altitude) distribution of concentrations of many species, during both day and night, for 10 years, from July 2002 to April 2012. Being a limb sounding instrument, the focus of MIPAS measurements was the study of the atmosphere from the upper troposphere to the stratosphere and above, up to the mesosphere. The interest in these measurements goes beyond the end of the mission, as they can be used in long time series of data to determine changes in our planet's climate. To this purpose, it is therefore important to continue improving their quality. The quality of MIPAS L2 products depends on the quality of the L1 products, on the L2 model accuracy, on the quality of auxiliary data, particularly on spectroscopic data. For the last reanalysis of the whole MIPAS mission, a significant effort was made by the MIPAS Quality Working Group, supported by ESA, to improve both L1 and L2 processors, as well as spectroscopy, with the objectives of obtaining L2 products with increased accuracy, better temporal stability, and a larger number of retrieved species. Here we present the full mission dataset, including vertical profiles of 21 trace species plus temperature, obtained by applying the latest version of ESA L2 processor (ORM V8) to the MIPAS L1 data obtained with version 8 of the L1 processor. The impact of the improvements of both L1 and L2 processors on the quality of the L2 products is presented, as well as results of the validation against independent correlative measurements.

Published
2020

9. Assessment of Quality of MIPAS ESA V8 Products

Author

Raspollini, Piera, Barbara, Flavio, Birk, Manfred, Ceccherini, Simone, Dehn, Angelika, Gai, M., Dinelli, Bianca Maria, Dudhia, Anu, Flaud, J.-M., Hoepfner, Michael, Hubert, Daan, Keppens, Arno, Kiefer, Michael, Kleinert, Anne, Moore, D., Papandrea, Enzo, Perron, Gaétan, Piro, A., López-Puertas, Manuel, Oelhaf, Hermann, Pettinari, Paolo, Remedios, John, Ridolfi, Marco, Sgheri, L., Wagner, Georg, Wetzel, G., and Zoppetti, Nicole

Subjects
data product quality, MIPAS/ENVISAT
Published
2019

11. Anatomie und Entwicklungsgeschichte der Mundhöhle und des Rachens

Author

Wetzel, G., Adrion, W., editor, Albrecht, W., editor, Alexander, G., editor, Amersbach, K., editor, Anton, G., editor, Beck, K., editor, Beck, O., editor, Beneke, R., editor, Benjamins, C. E., editor, Bentele, E., editor, Bever, G., editor, Birkholƶ, H., editor, Blohmke, A., editor, Blumenfeld, F., editor, Brock, W., editor, Brüggemann, A., editor, Brühl, G., editor, Brunner, H., editor, Burger, H., editor, Cemach, A. J., editor, Clausen, W., editor, Denker, A., editor, Dölger, R., editor, Eden, R., editor, Eckert-Möbius, A., editor, v. Eicken, C., editor, Elƶe, K., editor, Eschweiler, R., editor, Finder, G., editor, Flatau, Th. S., editor, Fleischmann, O., editor, Fremel, F., editor, Frese, O., editor, Friedberg, W., editor, Frühwald, V., editor, Giesswein, M., editor, Glas, E., editor, Goerke, M., editor, Graupner, K., editor, Grünberg, K., editor, Grünwald, L., editor, Hajek, M., editor, Harmer, L., editor, Haymann, L., editor, Hegener, J., editor, Heine, B., editor, Heims-Heymann, P., editor, Hinsberg, V., editor, Hofer, G., editor, Jesionek, A., editor, Imhofer, R., editor, Kahler, O., editor, Klestadt, W., editor, Knick, A., editor, Koenigsfeld, H., editor, Körner, O., editor, Kren, O., editor, Küpferle, L., editor, Kuttner, A., editor, Lautenschläger, A., editor, Lederer, L., editor, Lexer, E., editor, Linck, A., editor, Mangold, E., editor, Mann, M., editor, Marschik, H., editor, Marx, H., editor, Menƶel, K., editor, Meyer, Edmund, editor, Meyer, Max, editor, Minnigerode, W., editor, Muck, O., editor, Müller, Georg K., editor, Nadolecƶny, M., editor, Nager, F., editor, Neumann, H., editor, Neumayer, H., editor, Nühsmann, Th., editor, Oertel, B., editor, Passow, A., editor, Peter, K., editor, Peyser, A., editor, Pfeiffer, W., editor, Pick, F., editor, Ranƶi, E., editor, Rehn, E., editor, Ruttin, E., editor, Schaefer, K. L., editor, Scheibe, A., editor, Schilling, R., editor, Schlander, E., editor, Schlemmer, F., editor, Schlittler, E., editor, Schneider, P., editor, Schumacher, S., editor, Seifert, O., editor, Seiffert, A., editor, Sokolowsky, R., editor, v. Skramlik, E., editor, Sonnenkalb, V., editor, Specht, F., editor, Stenger, P., editor, Stern, H., editor, Steurer, O., editor, Stieda, A., editor, Streit, H., editor, Stupka, W., editor, Thost, A., editor, Uffenorde, W., editor, Urbantschitsch, E., editor, Vogel, C., editor, Wagener, O., editor, Wanner, F., editor, Wätjen, J., editor, Wetƶel, G., editor, Wittmaack, K., editor, Ƶange, J., editor, Ƶarniko, C., editor, Ƶausch, F., editor, Ƶwaardemaker, H., editor, and Wetzel, G., editor

Published
1925
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13. Validation of MIPAS-ENVISAT H2O operational data collected between July 2002 and March 2004

Author

Wetzel, G., Oelhaf, H., Berthet, G., Bracher, A., Cornacchia, C., Feist, D., Fischer, H., Fix, A., Iarlori, M., Kleinert, A., Lengel, A., Milz, M., Mona, L., Müller, S., Ovarlez, J., Pappalardo, G., Piccolo, C., Raspollini, P., Renard, J., Rizi, V., Rohs, S., Schiller, C., Stiller, G., Weber, M., and Zhang, G.

Subjects
Lidar, UPPER TROPOSPHERE, Water Vapour, satellite, HALOGEN OCCULTATION EXPERIMENT, GEOPHYSICAL VALIDATION, Humidity, lcsh:QC1-999, STRATOSPHERIC WATER-VAPOR, TROPOPAUSE, Remote Sensing, lcsh:Chemistry, MICHELSON INTERFEROMETER, BALLOON-BORNE, lcsh:QD1-999, LIMB EMISSION-SPECTRA, Validation, water vapor, ddc:550, DISTRIBUTIONS, TOTAL HYDROGEN BUDGET, Satellite Validation, lcsh:Physics
Abstract

Water vapour (H2O) is one of the operationally retrieved key species of the Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) instrument aboard the Environmental Satellite (ENVISAT) which was launched into its sun-synchronous orbit on 1 March 2002 and operated until April 2012. Within the MIPAS validation activities, independent observations from balloons, aircraft, satellites, and ground-based stations have been compared to European Space Agency (ESA) version 4.61 operational H2O data comprising the time period from July 2002 until March 2004 where MIPAS measured with full spectral resolution. No significant bias in the MIPAS H2O data is seen in the lower stratosphere (above the hygropause) between about 15 and 30 km. Differences of H2O quantities observed by MIPAS and the validation instruments are mostly well within the combined total errors in this altitude region. In the upper stratosphere (above about 30 km), a tendency towards a small positive bias (up to about 10%) is present in the MIPAS data when compared to its balloon-borne counterpart MIPAS-B, to the satellite instruments HALOE (Halogen Occultation Experiment) and ACE-FTS (Atmospheric Chemistry Experiment, Fourier Transform Spectrometer), and to the millimeter-wave airborne sensor AMSOS (Airborne Microwave Stratospheric Observing System). In the mesosphere the situation is unclear due to the occurrence of different biases when comparing HALOE and ACE-FTS data. Pronounced deviations between MIPAS and the correlative instruments occur in the lowermost stratosphere and upper troposphere, a region where retrievals of H2O are most challenging. Altogether it can be concluded that MIPAS H2O profiles yield valuable information on the vertical distribution of H2O in the stratosphere with an overall accuracy of about 10 to 30% and a precision of typically 5 to 15% – well within the predicted error budget, showing that these global and continuous data are very valuable for scientific studies. However, in the region around the tropopause retrieved MIPAS H2O profiles are less reliable, suffering from a number of obstacles such as retrieval boundary and cloud effects, sharp vertical discontinuities, and frequent horizontal gradients in both temperature and H2O volume mixing ratio (VMR). Some profiles are characterized by retrieval instabilities.

Published
2013
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15. Nachrichten aus der Archäologie

Author

Wetzel, G., Beyer, Brigitte, Filgis, Meinrad N., Kischka, Sybille, Kersting, U., Pfeiffer-Frohnert, U., Werner, Wolfgang Michael, and Schmidt, Hartwig

Published
1995

20. Spatio-temporal variations of NOy species in the northern latitudes stratosphere measured with the balloon-borne MIPAS instrument

Author

Wiegele, A., Kleinert, A., Oelhaf, H., Ruhnke, R., Wetzel, G., Friedl-Vallon, F., Lengel, A., Maucher, G., Nordmeyer, H., Fischer, H., Institute for Meteorology and Climate Research (IMK), Karlsruhe Institute of Technology (KIT), and EGU, Publication

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, lcsh:Chemistry, lcsh:QD1-999, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, lcsh:Physics, lcsh:QC1-999
Abstract

This paper presents the spatio-temporal distribution of NOy species at altitudes between 14 and 31 km as measured with the MIPAS-B instrument on the morning of 21 March 2003 in northern Scandinavia. At lower altitudes (below about 22 km), temperature variations, the distribution of ClONO2, and the tracer N2O reveal the dynamics through the edge of the late arctic polar vortex. At higher altitudes, continuous measurement before, during, and after sunrise provides information about photochemistry illustrating the evolution of the photochemically active gases NO2 and N2O5 around sunrise. The measured temporal evolution of NO2 and N2O5 is compared to box modelling that is run along backward calculated trajectories. While the comparison of measured and modelled N2O5 reveals significant differences, there is a good agreement between the model and observations for NO2 in terms of volume mixing ratios but the simulated decrease shortly after sunrise is underestimated compared to the measurements. The differences are attributed to the photolysis rates used in the box model calculations.

Published
2009

21. MIPAS IMK/IAA CFC-11 (CCl₃F) and CFC-12 (CCl₂F₂) measurements: accuracy, precision and long-term stability

Author

Eckert, E., Laeng, A., Lossow, S., Kellmann, S., Stiller, G., Von Clarmann, T., Glatthor, N., Höpfner, M., Kiefer, M., Oelhaf, H., Orphal, J., Funke, B., Grabowski, U., Haenel, F., Linden, A., Wetzel, G., Woiwode, W., Bernath, P. F., Boone, C., Dutton, G. S., Elkins, J. W., Engel, A., Gille, J. C., Kolonjari, F., Sugita, T., Toon, G. C., and Walker, K. A.

Subjects
Earth sciences, ddc:550
Abstract

Profiles of CFC-11 (CCl$_{3}$F) and CFC-12 (CCl$_{2}$F$_{2}$) of the Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) aboard the European satellite Envisat have been retrieved from versions MIPAS/4.61 to MIPAS/ 4.62 and MIPAS/5.02 to MIPAS/5.06 level-1b data using the scientific level-2 processor run by Karlsruhe Institute of Technology (KIT), Institute of Meteorology and Climate Research (IMK) and Consejo Superior de Investigaciones Científicas (CSIC), Instituto de Astrofísica de Andalucía (IAA). These profiles have been compared to measurements taken by the balloon-borne cryosampler, Mark IV (MkIV) and MIPAS-Balloon (MIPAS-B), the airborne MIPAS-STRatospheric aircraft (MIPAS-STR), the satellite-borne Atmospheric Chemistry Experiment Fourier transform spectrometer (ACE-FTS) and the High Resolution Dynamic Limb Sounder (HIRDLS), as well as the groundbased Halocarbon and other Atmospheric Trace Species (HATS) network for the reduced spectral resolution period (RR: January 2005–April 2012) of MIPAS. ACE-FTS, MkIV and HATS also provide measurements during the high spectral resolution period (full resolution, FR: July 2002–March 2004) and were used to validate MIPAS CFC-11 and CFC- 12 products during that time, as well as profiles from the Improved Limb Atmospheric Spectrometer, ILAS-II. In general, we find that MIPAS shows slightly higher values for CFC-11 at the lower end of the profiles (below 15 km) and in a comparison of HATS ground-based data and MIPAS measurements at 3 km below the tropopause. Differences range from approximately 10 to 50 pptv ( ~5–20 %) during the RR period. In general, differences are slightly smaller for the FR period. An indication of a slight high bias at the lower end of the profile exists for CFC-12 as well, but this bias is far less pronounced than for CFC-11 and is not as obvious in the relative differences between MIPAS and any of the comparison instruments. Differences at the lower end of the profile (below ~15 km) and in the comparison of HATS and MIPAS measurements taken at 3 km below the tropopause mainly stay within 10–50 pptv (corresponding to ~ 2–10% for CFC-12) for the RR and the FR period. Between ~15 and 30 km, most comparisons agree within 10–20 pptv (10–20 %), apart from ILAS-II, which shows large differences above ~17 km. Overall, relative differences are usually smaller for CFC-12 than for CFC-11. For both species – CFC-11 and CFC-12 – we find that differences at the lower end of the profile tend to be larger at higher latitudes than in tropical and subtropical regions. In addition, MIPAS profiles have a maximum in their mixing ratio around the tropopause, which is most obvious in tropical mean profiles. Comparisons of the standard deviation in a quiescent atmosphere (polar summer) show that only the CFC-12 FR error budget can fully explain the observed variability, while for the other products (CFC-11 FR and RR and CFC-12 RR) only two-thirds to three-quarters can be explained. Investigations regarding the temporal stability show very small negative drifts in MIPAS CFC-11 measurements. These instrument drifts vary between ~1 and 3% decade$^{-1}$. For CFC-12, the drifts are also negative and close to zero up to ~30 km. Above that altitude, larger drifts of up to 50% decade$^{-1}$ appear which are negative up to ~35 km and positive, but of a similar magnitude, above.

Published
2015

22. Constraining the N2O5 UV absorption cross-section from spectroscopic trace gas measurements in the tropical mid-stratosphere

Author

Kritten, L, Butz, A, Chipperfield, MP, Dorf, M, Dhomse, S, Hossaini, R, Oelhaf, H, Prados-Roman, C, Wetzel, G, and Pfeilsticker, K

Abstract

The absorption cross-section of N2O5, σN2O5(λ, T), which is known from laboratory measurements with the uncertainty of a factor of 2 (Table 4-2 in JPL-2011, Sander et al., 2011), was investigated by balloon-borne observations of the relevant trace gases in the tropical mid-stratosphere. The method relies on the observation of the diurnal variation of NO2 supported by detailed photochemical modelling of NOy (NOx(= NO + NO2) + NO3 + 2N2O5 + ClONO2 + HO2NO2 +BrONO2 + HNO3) photochemistry. Simulations are initialised with O3 measured by direct sun observations, the NOy partitioning from MIPAS-B (Michelson Interferometer for Passive Atmospheric Sounding-Balloon) observations in similar air masses at nighttime, and all other relevant species from simulations of the SLIMCAT chemical transport model (CTM). Best agreement between the simulated and observed diurnal increase of NO2 is found if the σN2O5(λ, T) is scaled by a factor of 1.6 ± 0.8 in the UV-C (200–260 nm) and by a factor of 0.9 ± 0.26 in the UV-B/A (260–350 nm), compared to current recommendations. In consequence, at 30 km altitude, the N2O5 lifetime against photolysis becomes a factor of 0.77 shorter at solar zenith angle (SZA) of 30° than using the recommended σN2O5 (λ, T), and stays more or less constant at SZAs of 60°. Our scaled N2O5 photolysis frequency slightly reduces the lifetime (0.2–0.6%) of ozone in the tropical mid- and upper stratosphere, but not to an extent to be important for global ozone.

Published
2014

23. Constraining the N2O5 UV absorption cross section from spectroscopic trace gas measurements in the tropical mid-stratosphere

Author

Kritten, L., Butz, A., Chipperfield, M. P., Dorf, M., Dhomse, S., Hossaini, R., Oelhaf, H., Prados-Roman, C., Wetzel, G., and Pfeilsticker, K.

Subjects
lcsh:Chemistry, Earth sciences, lcsh:QD1-999, ddc:550, lcsh:Physics, lcsh:QC1-999
Abstract

© 2014 Author(s). The absorption cross section of N2O5, σN2O5(λ, T), which is known from laboratory measurements with the uncertainty of a factor of 2 (Table 4-2 in (Jet Propulsion Laboratory) JPL-2011; the spread in laboratory data, however, points to an uncertainty in the range of 25 to 30%, Sander et al., 2011), was investigated by balloon-borne observations of the relevant trace gases in the tropical mid-stratosphere. The method relies on the observation of the diurnal variation of NO2by limb scanning DOAS (differential optical absorption spectroscopy) measurements (Weidner et al., 2005; Kritten et al., 2010), supported by detailed photochemical modelling of NOy(NOx(=NO + NO2) + NO3+ 2N2O5+ ClONO2+ HO2NO2+ BrONO2+ HNO3) photochemistry and a non-linear least square fitting of the model result to the NO2observations. Simulations are initialised with O3measured by direct sun observations, the NOypartitioning from MIPAS-B (Michelson Interferometer for Passive Atmospheric Sounding-Balloon-borne version) observations in similar air masses at night-time, and all other relevant species from simulations of the SLIMCAT (Single Layer Isentropic Model of Chemistry And Transport) chemical transport model (CTM). Best agreement between the simulated and observed diurnal increase of NO2is found if the σN2O5(λ, T) is scaled by a factor of 1.6 ± 0.8 in the UV-C (200-260 nm) and by a factor of 0.9 ± 0.26 in the UV-B/A (260-350 nm), compared to current recommendations. As a consequence, at 30 km altitude, the N2O5lifetime against photolysis becomes a factor of 0.77 shorter at solar zenith angle (SZA) of 30° than using the recommended σN2O5(λ, T), and stays more or less constant at SZAs of 60°. Our scaled N2O5photolysis frequency slightly reduces the lifetime (0.2-0.6%) of ozone in the tropical mid-and upper stratosphere, but not to an extent to be important for global ozone.

Published
2014

24. MIPAS IMK/IAA CFC-11 (CCl<sub>3</sub>F) and CFC-12 (CCl<sub>2</sub>F<sub>2</sub>) measurements: accuracy, precision and long-term stability

Author

Eckert, E., primary, Laeng, A., additional, Lossow, S., additional, Kellmann, S., additional, Stiller, G., additional, von Clarmann, T., additional, Glatthor, N., additional, Höpfner, M., additional, Kiefer, M., additional, Oelhaf, H., additional, Orphal, J., additional, Funke, B., additional, Grabowski, U., additional, Haenel, F., additional, Linden, A., additional, Wetzel, G., additional, Woiwode, W., additional, Bernath, P. F., additional, Boone, C., additional, Dutton, G. S., additional, Elkins, J. W., additional, Engel, A., additional, Gille, J. C., additional, Kolonjari, F., additional, Sugita, T., additional, Toon, G. C., additional, and Walker, K. A., additional

Published
2016
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26. Reconciliation of essential process parameters for an enhanced predictability of Arctic stratospheric ozone loss and its climate interactions

Author

Hobe, M. Von, Bekki, S., Borrmann, S., Cairo, F., D'Amato, F., Di Donfrancesco, G., Dörnbrack, A., Ebersoldt, A., Ebert, M., Emde, C., Engel, I., Ern, M., Frey, W., Genco, S., Griessbach, S., Grooß, J.-U., Gulde, T., Günther, G., Hösen, E., Hoffmann, L., Homonnai, V., Hoyle, C. R., Isaksen, I. S. A., Jackson, D. R., Jánosi, I. M., Jones, R. L., Kandler, K., Kalicinsky, C., Keil, A., Khaykin, S. M., Khosrawi, F., Kivi, R., Kuttippurath, J., Laube, J. C., Lefèvre, F., Lehmann, R., Ludmann, S., Luo, B. P., Marchand, M., Meyer, J., Mitev, V., Molleker, S., Müller, R., Oelhaf, H., Olschewski, F., Orsolini, Y., Peter, T., Pfeilsticker, K., Piesch, C., Pitts, M. C., Poole, L. R., Pope, F. D., Ravegnani, F., Rex, M., Riese, M., Röckmann, T., Rognerud, B., Roiger, A., Rolf, C., Santee, M. L., Scheibe, M., Schiller, C., Schlager, H., Siciliani De Cumis, M., Sitnikov, N., Sovde, O. A., Spang, R., Spelten, N., Stordal, F., Sumi'ska-Ebersoldt, O., Ulanovski, A., Ungermann, J., Viciani, S., Volk, C. M., Vom Scheidt, M., Von Der Gathen, P., Walker, K., Wegner, T., Weigel, R., Weinbruch, S., Wetzel, G., Wienhold, F. G., Wohltmann, I., Woiwode, W., Young, I. A. K., Yushkov, V., Zobrist, B., and Stroh, F.

Subjects
Earth sciences, ddc:550
Published
2013

36. MIPAS IMK/IAA CFC-11 (CCl<sub>3</sub>F) and CFC-12 (CCl<sub>2</sub>F<sub>2</sub>) measurements: accuracy, precision and long-term stability

Author

Eckert, E., primary, Laeng, A., additional, Lossow, S., additional, Kellmann, S., additional, Stiller, G., additional, von Clarmann, T., additional, Glatthor, N., additional, Höpfner, M., additional, Kiefer, M., additional, Oelhaf, H., additional, Orphal, J., additional, Funke, B., additional, Grabowski, U., additional, Haenel, F., additional, Linden, A., additional, Wetzel, G., additional, Woiwode, W., additional, Bernath, P. F., additional, Boone, C., additional, Dutton, G. S., additional, Elkins, J. W., additional, Engel, A., additional, Gille, J. C., additional, Kolonjari, F., additional, Sugita, T., additional, Toon, G. C., additional, and Walker, K. A., additional

Published
2015
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37. Partitioning and budget of inorganic and organic chlorine species observed by MIPAS-B and TELIS in the Arctic in March 2011

Author

Wetzel, G., primary, Oelhaf, H., additional, Birk, M., additional, de Lange, A., additional, Engel, A., additional, Friedl-Vallon, F., additional, Kirner, O., additional, Kleinert, A., additional, Maucher, G., additional, Nordmeyer, H., additional, Orphal, J., additional, Ruhnke, R., additional, Sinnhuber, B.-M., additional, and Vogt, P., additional

Published
2015
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38. Infrared Absorption Cross Sections of ClOOCl - Laboratory Work and Application in MIPAS-B Measurements

Author

Birk, M., Wagner, G., Oelhaf, H., and Wetzel, G.

Subjects
chlorine peroxide, infrared absorption cross sections, ClO dimer, Fourier-transform spectroscopy, ClOOCl, MIPAS-B, Experimentelle Verfahren, atmospheric remote sensing
Abstract

Chlorine peroxide, ClOOCl, is involved in the ozone depletion cycle in polar perturbed chemistry (e.g. antarctic ozone hole). Despite the importance there has been no direct detection of this molecule in the atmosphere due to the missing spectroscopic database and rather weak atmospheric infrared spectra. The first part of the present paper will report on work on mid infrared absorption cross sections of ClOOCl already done in 2000. ClOOCl was produced in a flow reaction of Cl and Cl2O via ClO self reaction below 260 K. Number densities were derived from far infrared measurements utilizing intensities of pure rotational transitions. Measurements were carried out with a high resolution Bruker IFS120HR Fourier-transform spectrometer. A coolable 80 m absorption path multireflexion cell was applied for the subsequent FIR/MIR measurements. Although high resolution structure was partly resolved due to the high complexity (heavy molecule, four isotopologues, internal rotation) absorption cross sections at two different temperatures and total pressures were measured and supplied as spectroscopic database. The second part will show the first direct atmospheric observations of ClOOCl from MIPAS-B (Michelson Interferometer for Passive Atmospheric Sounding) balloon-based measurements from Kiruna (Sweden) on 11 January 2001 and 20/21 March 2003 with nighttime values of nearly 1.1 ppbv at 20 km.

Published
2010

40. Validation of water vapour profiles (version 13) retrieved by the IMK/IAA scientific retrieval processor based on full resolution spectra measrued by MIPAS on board ENVISAT

Author

Milz, M., Clarmann, T.v., Grabowski, U., Griesfeller, A., Haefele, A., Höpfner, M., Kämpfer, M., Kellmann, S., Linden, A., Müller, S., Nakajima, H., Oelhaf, H., Bernath, P., Remsberg, E., Rohs, S., Russell III, J.M., Schiller, C., Stiller, G., Sugita, T., Tanaka, T., Vömel, H., Walker, K., Wetzel, G., Boone, C., Yokota, T., Yushkov, V., Zhang, G., Buehler, S.A., Chauhan, S., Deuber, B., Feist, D.G., Funke, B., and Glatthor, N.

Subjects
ddc:550
Published
2009

42. Validation of MIPAS-ENVISAT NO2 operational data

Author

Wetzel, G., Bracher, A., Funke, B., Goutail, Florence, Hendrick, F., Lambert, J.-C., Mikuteit, S., Piccolo, C., Pirre, Michel, Bazureau, Ariane, Belotti, C., Blumenstock, T., De Mazière, M., Fischer, H., Huret, Nathalie, Ionov, D., López-Puertas, M., Maucher, G., Oelhaf, H., Pommereau, Jean-Pierre, Ruhnke, R., Sinnhuber, M., Stiller, G., Van Roozendael, M., Zhang, G., Institute for Meteorology and Climate Research (IMK), Karlsruhe Institute of Technology (KIT), Institute of Environmental Physics and Remote Sensing [Bremen] (IUP/IFE), University of Bremen, Instituto de Astrofísica de Andalucía (IAA), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Service d'aéronomie (SA), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Belgian Institute for Space Aeronomy / Institut d'Aéronomie Spatiale de Belgique (BIRA-IASB), University of Oxford [Oxford], Laboratoire de physique et chimie de l'environnement (LPCE), Université d'Orléans (UO)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Istituto di Fisica Applicata 'Nello Carrara' (IFAC), Consiglio Nazionale delle Ricerche [Roma] (CNR), Institut für Meteorologie und Klimaforschung (IMK), Karlsruher Institut für Technologie (KIT), Consejo Superior de Investigaciones Científicas [Spain] (CSIC), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ), University of Oxford, Institut national des sciences de l'Univers (INSU - CNRS)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS), and National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere
Abstract

International audience; The Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) instrument was launched aboard the environmental satellite ENVISAT into its sun-synchronous orbit on 1 March 2002. The short-lived species NO2 is one of the key target products of MIPAS that are operationally retrieved from limb emission spectra measured in the stratosphere and mesosphere. Within the MIPAS validation activities, a large number of independent observations from balloons, satellites and ground-based stations have been compared to European Space Agency (ESA) version 4.61 operational NO2 data comprising the time period from July 2002 until March 2004 where MIPAS measured with full spectral resolution. Comparisons between MIPAS and balloon-borne observations carried out in 2002 and 2003 in the Arctic, at mid-latitudes, and in the tropics show a very good agreement below 40 km altitude with a mean deviation of roughly 3%, virtually without any significant bias. The comparison to ACE satellite observations exhibits only a small negative bias of MIPAS which appears not to be significant. The independent satellite instruments HALOE, SAGE II, and POAM III confirm in common for the spring-summer time period a negative bias of MIPAS in the Arctic and a positive bias in the Antarctic middle and upper stratosphere exceeding frequently the combined systematic error limits. In contrast to the ESA operational processor, the IMK/IAA retrieval code allows accurate inference of NO2 volume mixing ratios under consideration of all important non-LTE processes. Large differences between both retrieval results appear especially at higher altitudes, above about 50 to 55 km. These differences might be explained at least partly by non-LTE under polar winter conditions but not at mid-latitudes. Below this altitude region mean differences between both processors remain within 5% (during night) and up to 10% (during day) under undisturbed (September 2002) conditions and up to 40% under perturbed polar night conditions (February and March 2004). The intercomparison of ground-based NDACC observations shows no significant bias between the FTIR measurements in Kiruna (68° N) and MIPAS in summer 2003 but larger deviations in autumn and winter. The mean deviation over the whole comparison period remains within 10%. A mean negative bias of 15% for MIPAS daytime and 8% for nighttime observations has been determined for UV-vis comparisons over Harestua (60° N). Results of a pole-to-pole comparison of ground-based DOAS/UV-visible sunrise and MIPAS mid-morning column data has shown that the mean agreement in 2003 falls within the accuracy limit of the comparison method. Altogether, it can be indicated that MIPAS NO2 profiles yield valuable information on the vertical distribution of NO2 in the lower and middle stratosphere (below about 45 km) during day and night with an overall accuracy of about 10–20% and a precision of typically 5–15% such that the data are useful for scientific studies. In cases where extremely high NO2 occurs in the mesosphere (polar winter) retrieval results in the lower and middle stratosphere are less accurate than under undisturbed atmospheric conditions.

Published
2007
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43. Bias determination and precision validation of ozone profiles from MIPAS-Envisat retrieved with the IMK-IAA processor [Discussion paper]

Author

Steck, T., Clarmann, Thomas von, Fischer, H., Funke, Bernd, Glatthor, N., Grabowski, Udo, Höpfner, Michael, Kellmann, Sylvia, Kiefer, Michael, Linden, A., Milz, ‪Mathias, Stiller, Gabriele P., Wang, D. Y., Allaart, Marc, Blumenstock, Thomas, Gathen, Peter von der, Hansen, G., Hase, Frank, Hochschild, G., Kopp, G., Kyrö, Esko, Oelhaf, H., Raffalski, Uwe, Redondas, Alberto, Remsberg, E., Russell III, James M., Stebel, K., Steinbrecht, Wolfgang, Wetzel, G., Yela, Margarita, and Zhang, Gu

Subjects
Stratospheric ozone, Vertical ozone profiles, Ozono estratosférico, Perfil vertical del ozono, Michelson interferometer for passive atmospheric sounding
Abstract

This paper characterizes vertical ozone profiles retrieved with the IMK-IAA (Institute for Meteorology and Climate Research, Karlsruhe – Instituto de Astrofisica de Andalucia) science-oriented processor from high spectral resolution data (until March 2004) measured by the Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) aboard the environmental satellite Envisat. Bias determination and precision validation is performed on the basis of correlative measurements by ground-based lidars, Fourier transform infrared spectrometers, and microwave radiometers as well as balloon-borne ozonesondes, the balloon-borne version of MIPAS, and two satellite instruments (Halogen Occultation Experiment and Polar Ozone and Aerosol Measurement III). Percentage mean differences between MIPAS and the comparison instruments for stratospheric ozone are generally within ±10%. The precision in this altitude region is estimated at values between 5 and 10% which gives an accuracy of 15 to 20%. Below 18 km, the spread of the percentage mean differences is larger and the precision degrades to values of more than 20% depending on altitude and latitude. The main reason for the degraded precision at low altitudes is attributed to undetected thin clouds which affect MIPAS retrievals, and to the influence of uncertainties in the water vapor concentration.

Published
2007

44. Geophysical validation of MIPAS-ENVISAT operational ozone data

Author

Cortesi, U. Lambert, J.C. De Clercq, C. Bianchini, G. Blumenstock, T. Bracher, A. Castelli, E. Catoire, V. Chance, K.V. De Mazière, M. Demoulin, P. Godin-Beekmann, S. Jones, N. Jucks, K. Keim, C. Kerzenmacher, T. Kuellmann, H. Kuttippurath, J. Iarlori, M. Liu, G.Y. Liu, Y. McDermid, I.S. Meijer, Y.J. Mencaraglia, F. Mikuteit, S. Oelhaf, H. Piccolo, C. Pirre, M. Raspollini, P. Ravegnani, F. Reburn, W.J. Redaelli, G. Remedios, J.J. Sembhi, H. Smale, D. Steck, T. Taddei, A. Varotsos, C. Vigouroux, C. Waterfall, A. Wetzel, G. Wood, S.

Abstract

The Michelson Interferometer for Passive Atmospheric Sounding (MIPAS), on-board the European ENVIronmental SATellite (ENVISAT) launched on 1 March 2002, is a middle infrared Fourier Transform spectrometer measuring the atmospheric emission spectrum in limb sounding geometry. The instrument is capable to retrieve the vertical distribution of temperature and trace gases, aiming at the study of climate and atmospheric chemistry and dynamics, and at applications to data assimilation and weather forecasting. MIPAS operated in its standard observation mode for approximately two years, from July 2002 to March 2004, with scans performed at nominal spectral resolution of 0.025 cm -1 and covering the altitude range from the mesosphere to the upper troposphere with relatively high vertical resolution (about 3 km in the stratosphere). Only reduced spectral resolution measurements have been performed subsequently. MIPAS data were re-processed by ESA using updated versions of the Instrument Processing Facility (IPF v4.61 and v4.62) and provided a complete set of level-2 operational products (geolocated vertical profiles of temperature and volume mixing ratio of H2O, O3, HNO3, CH4, N2O and NO2) with quasi continuous and global coverage in the period of MIPAS full spectral resolution mission. In this paper, we report a detailed description of the validation of MIPAS-ENVISAT operational ozone data, that was based on the comparison between MIPAS v4.61 (and, to a lesser extent, v4.62) O3 VMR profiles and a comprehensive set of correlative data, including observations from ozone sondes, ground-based lidar, FTIR and microwave radiometers, remote-sensing and in situ instruments on-board stratospheric aircraft and balloons, concurrent satellite sensors and ozone fields assimilated by the European Center for Medium-range Weather Forecasting. A coordinated effort was carried out, using common criteria for the selection of individual validation data sets, and similar methods for the comparisons. This enabled merging the individual results from a variety of independent reference measurements of proven quality (i.e. well characterized error budget) into an overall evaluation of MIPAS O3 data quality, having both statistical strength and the widest spatial and temporal coverage. Collocated measurements from ozone sondes and ground-based lidar and microwave radiometers of the Network for the Detection Atmospheric Composition Change (NDACC) were selected to carry out comparisons with time series of MIPAS O 3 partial columns and to identify groups of stations and time periods with a uniform pattern of ozone differences, that were subsequently used for a vertically resolved statistical analysis. The results of the comparison are classified according to synoptic and regional systems and to altitude intervals, showing a generally good agreement within the comparison error bars in the upper and middle stratosphere. Significant differences emerge in the lower stratosphere and are only partly explained by the larger contributions of horizontal and vertical smoothing differences and of collocation errors to the total uncertainty. Further results obtained from a purely statistical analysis of the same data set from NDACC ground-based lidar stations, as well as from additional ozone soundings at middle latitudes and from NDACC ground-based FTIR measurements, confirm the validity of MIPAS O3 profiles down to the lower stratosphere, with evidence of larger discrepancies at the lowest altitudes. The validation against O3 VMR profiles using collocated observations performed by other satellite sensors (SAGE II, POAM III, ODIN-SMR, ACE-FTS, HALOE, GOME) and ECMWF assimilated ozone fields leads to consistent results, that are to a great extent compatible with those obtained from the comparison with ground-based measurements. Excellent agreement in the full vertical range of the comparison is shown with respect to collocated ozone data from stratospheric aircraft and balloon instruments, that was mostly obtained in very good spatial and temporal coincidence with MIPAS scans. This might suggest that the larger differences observed in the upper troposphere and lowermost stratosphere with respect to collocated ground-based and satellite O3 data are only partly due to a degradation of MIPAS data quality. They should be rather largely ascribed to the natural variability of these altitude regions and to other components of the comparison errors. By combining the results of this large number of validation data sets we derived a general assessment of MIPAS v4.61 and v4.62 ozone data quality. A clear indication of the validity of MIPAS O3 vertical profiles is obtained for most of the stratosphere, where the mean relative difference with the individual correlative data sets is always lower than ±10%. Furthermore, these differences always fall within the combined systematic error (from 1 hPa to 5OhPa) and the standard deviation is fully consistent with the random error of the comparison (from 1 hPa to ∼~30-40hPa). A degradation in the quality of the agreement is generally observed in the lower stratosphere and upper troposphere, with biases up to 25% at 100 hPa and standard deviation of the global mean differences up to three times larger than the combined random error in the range 50-100 hPa. The larger differences observed at the bottom end of MIPAS retrieved profiles can be associated, as already noticed, to the effects of stronger atmospheric gradients in the UTLS that are perceived differently by the various measurement techniques. However, further components that may degrade the results of the comparison at lower altitudes can be identified as potentially including cloud contamination, which is likely not to have been fully filtered using the current settings of the MIPAS cloud detection algorithm, and in the linear approximation of the forward model that was used for the a priori estimate of systematic error components. The latter, when affecting systematic contributions with a random variability over the spatial and temporal scales of global averages, might result in an underestimation of the random error of the comparison and add up to other error sources, such as the possible underestimates of the p and T error propagation based on the assumption of a 1K and 2% uncertainties, respectively, on MIPAS temperature and pressure retrievals. At pressure lower than 1 hPa, only a small fraction of the selected validation data set provides correlative ozone data of adequate quality and it is difficult to derive quantitative conclusions about the performance of MIPAS O2 retrieval for the topmost layers.

Published
2007

45. Validation of MIPAS ClONO₂ measurements

Author

Höpfner, M., Clarmann, T. von, Fischer, H., Funke, B., Glatthor, N., Grabowski, U., Kellmann, S., Kiefer, M., Linden, A., Milz, M., Steck, T., Stiller, G. P., Bernath, P., Blom, C. E., Blumenstock, T., Boone, C., Chance, K., Coffey, M. T., Friedl-Vallon, F., Griffith, D., Hannigan, J. W., Hase, F., Jones, N., Jucks, K. W., Keim, C., Kleinert, A., Kouker, W., Liu, G. Y., Mahieu, E., Mellqvist, J., Mikuteit, S., Notholt, J., Oelhaf, H., Piesch, C., Reddmann, T., Ruhnke, R., Schneider, M., Strandberg, A., Toon, G., Walker, K. A., Warneke, T., Wetzel, G., Wood, S., and Zander, R.

Subjects
Earth sciences, ddc:550
Published
2007
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46. Geophysical validation of temperature retrieved by the ESA processor from MIPAS/ENVISAT atmoshperic limb-emission measurements

Author

Ridolfi, M., Blum, U., Carli, B., Catoire, V., Ceccherini, S., Claude, H., Clercq, C. de, Fricke, K.H., Friedl-Vallon, F., Iarlori, M., Keckhut, P., Kerridge, B., Lambert, J.-C., Meijer, Y.J., Mona, L., Oelhaf, H., Pappalardo, G., Pirre, M., Rizi, V., Robert, C., Swart, D., Clarmann, T. von, Waterfall, A., Wetzel, G., and Publica

Abstract

The Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) has been operating since March 2002 onboard of the ENVIronmental SATellite of the European Space Agency (ESA). The high resolution (0.035 cmE-1 full width half maximum, unapodized) limb-emission measurements acquired by MIPAS in the first two years of operation have very good geographical and temporal coverage and have been re-processed by ESA with the most recent versions (4.61 and 4.62) of the inversion algorithms. The products of this processing chain are pressures at the tangent points and geolocated profiles of temperature and of the volume mixing ratios of six key atmospheric constituents: H2O, O3, HNO3, CH4, N2O and NO2. As for all the measurements made with innovative instruments and techniques, this data set requires a thorough validation. In this paper we present a geophysical validation of the temperature profiles derived from MIPAS measurements by the ESA retrieval algorithm. The validation is carried-out by comparing MIPAS temperature with correlative measurements made by radiosondes, lidars, in-situ and remote sensors operated either from the ground or stratospheric balloons. The results of the intercomparison indicate that the bias of the MIPAS profiles is generally smaller than 1 or 2 K depending on altitude. Furthermore we find that, especially at the edges of the altitude range covered by the MIPAS scan, the random error estimated from the intercomparison is larger (typically by a factor of two to three) than the corresponding estimate derived on the basis of error propagation. In this work we also characterize the discrepancies between MIPAS temperature and the temperature fields resulting from the analyses of the European Centre for Medium-range Weather Forecasts (ECMWF). The bias and the standard deviation of these discrepancies are consistent with those obtained when comparing MIPAS to correlative measurements; however, in this case the detected bias has a peculiar behavior as a function of altitude. This behavior is very similar to that observed in previous studies and is suspected to be due to vertical oscillations in the ECMWF temperature. The current understanding is that, at least in the upper stratosphere (above 10 hPa), these oscillations are caused by a discrepancy between model biases and biases of assimilated radiances from primarily nadir sounders. This work is licensed under a Creative Commons License. http://www.atmos-chem-phys-discuss.net/7/5439/2007/

Published
2007

47. Geophysical validation of MIPAS-ENVISAT operational ozone data

Author

Cortesi, U., Lambert, J. C., De Clercq, C., Bianchini, G., Blumenstock, T., Bracher, Astrid, Castelli, E., Catoire, V., Chance, K. V., De Maziere, M., Demoulin, P., Godin-Beekman, S., Jones, N., Jucks, K., Keim, C., Kerzenmacher, T., Kuellmann, H., Kuttippurath, J., Iarlori, M., Liu, Y., McDermid, I. S., Meijer, Y., Mencaraglia, F., Oelhaf, H., Piccolo, C., Pirre, M., Raspollini, P., Ravegnani, F., Reburn, W. J., Redaelli, G., Sembhi, H., Smale, D., Steck, T., Taddei, A., Varotsos, K., Vigouroux, C., Waterfall, A., Wetzel, G., and Wood, S.

Abstract

Part of the abstract: The Michelson Interferometer for Passive AtmosphericSounding (MIPAS), on-board the European ENVIronmentalSATellite (ENVISAT) launched on 1 March 2002,is a middle infrared Fourier Transform spectrometer measuringthe atmospheric emission spectrum in limb sounding geometry.The instrument is capable to retrieve the vertical distributionMIPAS data were re-processed by ESA using updated versions ofthe Instrument Processing Facility (IPF v4.61 and v4.62) andprovided a complete set of level-2 operational products (geolocatedvertical profiles of temperature and volume mixingratio of H2O, O3, HNO3, CH4, N2O and NO2). MIPAS operated in its standard observation mode for approximately two years, from July 2002 to March 2004. MIPAS data were re-processed by ESA using updated versions of the Instrument Processing Facility (IPF v4.61 and v4.62) and provided a complete set of level-2 operational products (geolocated vertical profiles of temperature and volume mixing ratio of H2O, O3, HNO3, CH4, N2O and NO2). MIPAS operated in its standard observation mode from July 2002 to March 2004, covering the altitude range from the mesosphere to the upper troposphere with relatively high vertical resolution (about 3 km in the stratosphere). In this paper, we report a detailed description of the validation of MIPAS-ENVISAT operational ozone data, that was based on the comparison between MIPAS v4.61 (and, to a lesser extent, v4.62) O3 VMR profilesand a comprehensive set of correlative data, including observations from ozone sondes, ground-based lidar, FTIR and microwave radiometers, remote-sensing and in situ instruments on-board stratospheric aircraft and balloons, concurrent satellite sensors and ozone fields assimilated by theEuropean Center for Medium-range Weather Forecasting. A clear indication of the validity of MIPAS O3 vertical profiles is obtained for most of the stratosphere, where the mean relative difference with the individual correlative data sets is always lower than ±10%. Furthermore, these differences always fall within the combined systematic error (from1 hPa to 50 hPa) and the standard deviation is fully consistent with the random error of the comparison (from 1 hPa to 3040 hPa).

Published
2007

48. Validation and data characteristics of methane and nitrous oxide profiles observed by MIPAS and processed with version 4.61 algorithm

Author

Payen, Sébastien, Bureau, Jérôme, Camy-Peyret, Claude, Grunow, K., Payne, V., Bracher, A., Wetzel, G., Pirre, Michel, Kuttippurath, J., Glatthor, N., Stiller, G., Cortesi, U., Raspollini, P., Blumenstock, T., Mikuteit, S., Vigouroux, C., Engel, A., Volk, M. C., Piccolo, C., Butz, A., Laboratoire de Physique Moleculaire pour l'Atmosphere et l'Astrophysique (LPMAA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), Institut für Meteorologie [Berlin], Freie Universität Berlin, Atmospheric and Environmental Research, Inc. (AER), Institute of Environmental Physics and Remote Sensing [Bremen] (IUP/IFE), University of Bremen, Institute for Meteorology and Climate Research (IMK), Karlsruhe Institute of Technology (KIT), Laboratoire de physique et chimie de l'environnement (LPCE), Institut national des sciences de l'Univers (INSU - CNRS)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS), Institute of Environmental Physics [Bremen] (IUP), Istituto di Fisica Applicata 'Nello Carrara' (IFAC), National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), Belgian Institute for Space Aeronomy / Institut d'Aéronomie Spatiale de Belgique (BIRA-IASB), Institut für Atmosphäre und Umwelt [Frankfurt/Main] (IAU), Goethe-Universität Frankfurt am Main, Department of Atmospheric, Oceanic and Planetary Physics [Oxford] (AOPP), University of Oxford, Institut für Umweltphysik [Heidelberg], Universität Heidelberg [Heidelberg] = Heidelberg University, Université d'Orléans (UO)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Consiglio Nazionale delle Ricerche [Roma] (CNR), University of Oxford [Oxford], and Universität Heidelberg [Heidelberg]

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere
Abstract

The ENVISAT validation programme for the atmospheric instruments MIPAS, SCIAMACHY and GOMOS is based on a number of balloon-bone, aircraft and ground-based correlative measurements. In particular the activities of validation scientists were coordinated by ESA within the ENVISAT Stratospheric Aircraft and Balloon Campaign or ESABC. In parallel to the contribution of the individual validation teams, the present work provides a synthesis of comparisons performed between MIPAS CH4 and N2O profiles produced by the current ESA operational software (Instrument Processing Facility version 4.61 or IPF v4.61) and correlative measurements obtained from balloon and aircraft experiments as well as from satellite sensors or from ground-based instruments.

Published
2006

49. Validation of nitric acid retrieved by the IMK-IAA processor from MIPAS/ENVISAT measurements

Author

Wang, D. Y., Höpfner, M., Gizaw Mengistu Tsidu, Stiller, G. P., Clarmann, T., Fischer, H., Blumenstock, T., Glatthor, N., Grabowski, U., Hase, F., Kellmann, S., Linden, A., Milz, M., Oelhaf, H., Schneider, M., Steck, T., Wetzel, G., López-Puertas, M., Funke, B., Koukouli, M. E., Nakajima, H., Sugita, T., Irie, H., Urban, J., Murtagh, D., Santee, M. L., Toon, G., Gunson, M. R., Irion, F. W., Boone, C. D., Walker, K., Bernath, P. F., Forschungszentrum Karlsruhe und Universität Karlsruhe, Physics Department [UNB], University of New Brunswick (UNB), Department of Physics, Okayama University, Instituto de Astrofísica de Andalucía (IAA), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Physics Department, National Institute for Environmental Studies (NIES), Frontier Research Center for Global Change (FRCGC), Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Chalmers University of Technology [Göteborg], Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Department of Chemistry [Waterloo], University of Waterloo [Waterloo], EGU, Publication, Institute for Meteorology and Climate Research (IMK), and Karlsruhe Institute of Technology (KIT)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, 13. Climate action, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere
Abstract

International audience; The Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) onboard the ENVISAT satellite provides profiles of temperature and various trace-gases from limb-viewing mid-infrared emission measurements. The stratospheric nitric acid (HNO3) from September 2002 to March 2004 was retrieved from the MIPAS observations using the science-oriented data processor developed at the Institut für Meteorologie und Klimaforschung (IMK), which is complemented by the component of non-local thermodynamic equilibrium (non-LTE) treatment from the Instituto de Astrofísica de Andalucía (IAA). The IMK-IAA research product, different from the ESA operational product, is validated in this paper by comparison with a number of reference data sets. Individual HNO3 profiles of the IMK-IAA MIPAS show good agreement with those of the balloon-borne version of MIPAS (MIPAS-B) and the infrared spectrometer MkIV, with small differences of less than 0.5 ppbv throughout the entire altitude range up to about 38 km, and below 0.2 ppbv above 30 km. However, the degree of consistency is largely affected by their temporal and spatial coincidence, and differences of 1 to 2 ppbv may be observed between 22 and 26 km at high latitudes near the vortex boundary, due to large horizontal inhomogeneity of HNO3. Statistical comparisons of MIPAS IMK-IAA HNO3 VMRs with respect to those of satellite measurements of Odin/SMR, ILAS-II, ACE-FTS, as well as the MIPAS ESA product show good consistency. The mean differences are generally ±0.5 ppbv and standard deviations of the differences are of 0.5 to 1.5 ppbv. The maximum differences are 2.0 ppbv around 20 to 25 km. This gives confidence in the general reliability of MIPAS HNO3 VMR data and the other three satellite data sets.

Published
2006

50. Validation of MIPAS ClONO2 measurements

Author

Höpfner, M., Clarmann, T., Fischer, H., Funke, B., Glatthor, N., Grabowski, U., Kellmann, S., Kiefer, M., Linden, A., Milz, M., Steck, T., Stiller, G. P., Bernath, P., Blom, C. E., Blumenstock, Th, Boone, C., Chance, K., Coffey, M. T., Friedl-Vallon, F., Griffith, D., Hannigan, J. W., Hase, F., Jones, N., Jucks, K. W., Keim, C., Kleinert, A., Kouker, W., Liu, G. Y., Mahieu, E., Mellqvist, J., Mikuteit, S., Justus Notholt, Oelhaf, H., Piesch, C., Reddmann, T., Ruhnke, R., Schneider, M., Strandberg, A., Toon, G., Walker, K. A., Warneke, T., Wetzel, G., Wood, S., Zander, R., Institute for Meteorology and Climate Research (IMK), Karlsruhe Institute of Technology (KIT), Instituto de Astrofísica de Andalucía (IAA), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Department of Chemistry, Harvard-Smithsonian Center for Astrophysics (CfA), Harvard University [Cambridge]-Smithsonian Institution, Atmospheric Chemistry Division [Boulder], National Center for Atmospheric Research [Boulder] (NCAR), Institut d'Astrophysique et de Géophysique [Liège], Université de Liège, Department of Radio and Space Science [Göteborg], Chalmers University of Technology [Göteborg], Institut für Umweltphysik [Bremen] (IUP), Universität Bremen, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Institut für Umweltphysik [Heidelberg], Universität Heidelberg [Heidelberg], and National Institute of Water and Atmospheric Research [Wellington] (NIWA)

Subjects
lcsh:Chemistry, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, lcsh:QD1-999, lcsh:Physics, lcsh:QC1-999
Abstract

Altitude profiles of ClONO2 retrieved with the IMK (Institut für Meteorologie und Klimaforschung) science-oriented data processor from MIPAS/Envisat (Michelson Interferometer for Passive Atmospheric Sounding on Envisat) mid-infrared limb emission measurements between July 2002 and March 2004 have been validated by comparison with balloon-borne (Mark IV, FIRS2, MIPAS-B), airborne (MIPAS-STR), ground-based (Spitsbergen, Thule, Kiruna, Harestua, Jungfraujoch, Izaña, Wollongong, Lauder), and spaceborne (ACE-FTS) observations. With few exceptions we found very good agreement between these instruments and MIPAS with no evidence for any bias in most cases and altitude regions. For balloon-borne measurements typical absolute mean differences are below 0.05 ppbv over the whole altitude range from 10 to 39 km. In case of ACE-FTS observations mean differences are below 0.03 ppbv for observations below 26 km. Above this altitude the comparison with ACE-FTS is affected by the photochemically induced diurnal variation of ClONO2. Correction for this by use of a chemical transport model led to an overcompensation of the photochemical effect by up to 0.1 ppbv at altitudes of 30–35 km in case of MIPAS-ACE-FTS comparisons while for the balloon-borne observations no such inconsistency has been detected. The comparison of MIPAS derived total column amounts with ground-based observations revealed no significant bias in the MIPAS data. Mean differences between MIPAS and FTIR column abundances are 0.11±0.12×1014 cm−2 (1.0±1.1%) and −0.09±0.19×1014 cm−2 (−0.8±1.7%), depending on the coincidence criterion applied. χ2 tests have been performed to assess the combined precision estimates of MIPAS and the related instruments. When no exact coincidences were available as in case of MIPAS – FTIR or MIPAS – ACE-FTS comparisons it has been necessary to take into consideration a coincidence error term to account for χ2 deviations. From the resulting χ2 profiles there is no evidence for a systematic over/underestimation of the MIPAS random error analysis.

Published
2006

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