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233 results on '"Gumbel, Jörg"'

1. Flight model characterization of the wide-field off-axis telescope for the MATS satellite

Author

Park, Woojin, Hammar, Arvid, Pak, Soojong, Chang, Seunghyuk, Gumbel, Jörg, Megner, Linda, Christensen, Ole Martin, Rouse, Jordan, and Kim, Dae Wook

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

We present optical characterization, calibration, and performance tests of the Mesospheric Airglow/Aerosol Tomography Spectroscopy (MATS) satellite, which for the first time for a satellite applies a linear-astigmatism-free confocal off-axis reflective optical design. Mechanical tolerances of the telescope were investigated using Monte-Carlo methods and single-element perturbations. The sensitivity analysis results indicate that tilt errors of the tertiary mirror and a surface RMS error of the secondary mirror mainly degrade optical performance. From the Monte-Carlo simulation, the tolerance limits were calculated to $\pm$0.5 mm, $\pm$1 mm, and $\pm$0.15$^\circ$ for decenter, despace, and tilt, respectively. We performed characterization measurements and optical tests with the flight model of the satellite. Multi-channel relative pointing, total optical system throughput, and distortion of each channel were characterized for end-users. Optical performance was evaluated by measuring modulation transfer function (MTF) and point spread function (PSF). The final MTF performance is 0.25 MTF at 20 lp/mm for the ultraviolet channel (304.5 nm), and 0.25 - 0.54 MTF at 10 lp/mm for infrared channels. The salient fact of the PSF measurement of this system is that there is no noticeable linear astigmatism detected over wide field of view (5.67$^\circ$ $\times$ 0.91$^\circ$). All things considered, the design method showed great advantages in wide field of view observations with satellite-level optical performance., Comment: 21 pages, 11 figures

Published
2020
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3. Sounding rocket project “PMWE” for investigation of polar mesosphere winter echoes

Author

Strelnikov, Boris, Staszak, Tristan, Latteck, Ralph, Renkwitz, Toralf, Strelnikova, Irina, Lübken, Franz-Josef, Baumgarten, Gerd, Fiedler, Jens, Chau, Jorge L., Stude, Joan, Rapp, Markus, Friedrich, Martin, Gumbel, Jörg, Hedin, Jonas, Belova, Evgenia, Hörschgen-Eggers, Marcus, Giono, Gabriel, Hörner, Igor, Löhle, Stefan, Eberhart, Martin, and Fasoulas, Stefanos

Published
2021
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6. Scale separation for gravity wave analysis from 3D temperature observations in the mesosphere and lower thermosphere (MLT) region.

Author

Linder, Björn, Preusse, Peter, Chen, Qiuyu, Christensen, Ole Martin, Krasauskas, Lukas, Megner, Linda, Ern, Manfred, and Gumbel, Jörg

Subjects
GRAVITY waves, WAVE analysis, MESOSPHERE, GENERAL circulation model, THERMOSPHERE, WAVENUMBER, ROSSBY waves
Abstract

MATS (Mesospheric Airglow/Aerosol Tomography and Spectroscopy) is a Swedish satellite designed to investigate atmospheric dynamics in the mesosphere and lower thermosphere (MLT). By observing structures in noctilucent clouds over polar regions and oxygen atmospheric-band (A-band) emissions globally, MATS will provide the research community with properties of the MLT atmospheric wave field. Individual A-band images taken by MATS's main instrument, a six-channel limb imager, are transformed through tomography and spectroscopy into three-dimensional temperature fields, within which the wave structures are embedded. To identify wave properties, particularly the gravity wave momentum flux, from the temperature field, smaller-scale perturbations (associated with the targeted waves) must be separated from large-scale background variations using a method of scale separation. This paper investigates the possibilities of employing a simple method based on smoothing polynomials to separate the smaller and larger scales. Using using synthetic tomography data based on the HIAMCM (HIgh Altitude Mechanistic general Circulation Model), we demonstrate that smoothing polynomials can be applied to MLT temperatures to obtain fields corresponding to global-scale separation at zonal wavenumber 18. The simplicity of the method makes it a promising candidate for studying wave dynamics in MATS temperature fields. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Scale separation for gravity wave analysis from 3D temperature observations in the MLT region.

Author

Linder, Björn, Preusse, Peter, Chen, Qiuyu, Christensen, Ole Martin, Krasauskas, Lukas, Megner, Linda, Ern, Manfred, and Gumbel, Jörg

Subjects
GRAVITY waves, WAVE analysis, NOCTILUCENT clouds, ATMOSPHERIC circulation, ATMOSPHERIC waves, WAVENUMBER, ROSSBY waves
Abstract

MATS (Mesospheric Airglow/Aerosol, Tomography & Spectroscopy) is a Swedish satellite designed to investigate atmospheric dynamics in the Mesosphere and Lower Thermosphere (MLT). From observing structures in noctilucent clouds over polar regions, and oxygen A-band emissions globally, MATS will supply the research community with properties of the MLT atmospheric wave field. Individual A-band images taken by the MATS main instrument, a 6-channel limb imager, are through tomography and spectroscopy turned into three-dimensional temperature fields in which the wave structures are embedded. To identify wave properties, in particular the gravity wave momentum flux, from the temperature field, smaller-scale perturbations, associated with the targeted waves, must be separated from large-scale background variations by a method of scale separation. This paper investigates the possibilities of employing a simple method based on smoothing polynomials to separate the smaller and larger scales. By using synthetic tomography data based on the HIAMCM (High Altitude Mechanistic Circulation Model) we demonstrate that smoothing polynomials can be applied to MLT temperatures to obtain fields corresponding to a global scale separation at zonal wavenumber 18. The simplicity of the method makes it a promising candidate for studying wave dynamics in the MATS temperature fields. [ABSTRACT FROM AUTHOR]

Published
2024
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10. The MATS satellite mission: Towards gravity wave parameters

Author

Linder, Björn, Megner, Linda, Preusse, Peter, Chen, Qiuyu, Christensen, Ole Martin, Gumbel, Jörg, Ern, Manfred, Murtagh, Donal, and Becker, Erich

Abstract

The Swedish satellite MATS was launched in November 2022. MATS derives three-dimensional temperature fields from the mesosphere and lower thermosphere by observing atmospheric airglow emissions and light scattered off noctilucent clouds. As propagating gravity waves introduce fluctuations in pressure, density and temperature, these measurements can be used to study the wave dynamics of this energetic atmospheric region. To correctly capture the gravity wave spectra, wave-induced perturbations have to be isolated from larger scale fluctuations of the background atmosphere. Based on measurements made by MATS during the initial operational months, as well as synthetic tomography data, we investigate how waves affect the MATS measurements, and how their properties can be derived., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

12. Opinion : Recent developments and future directions in studying the mesosphere and lower thermosphere

Author

Plane, John M. C., Gumbel, Jörg, Kalogerakis, Konstantinos S., Marsh, Daniel R., von Savigny, Christian, Plane, John M. C., Gumbel, Jörg, Kalogerakis, Konstantinos S., Marsh, Daniel R., and von Savigny, Christian

Abstract

This article begins with a review of important advances in the chemistry and related physics of the mesosphere and lower thermosphere (MLT) region of the atmosphere that have occurred over the past 2 decades, since the founding of Atmospheric Chemistry and Physics. The emphasis here is on chemistry, but we also discuss recent findings on atmospheric dynamics and forcings to the extent that these are important for understanding MLT composition and chemistry. Topics that are covered include observations, with satellite, rocket and ground-based techniques; the variability and connectedness of the MLT on various length scales and timescales; airglow emissions; the cosmic dust input and meteoric metal layers; and noctilucent/polar mesospheric ice clouds. The paper then concludes with a discussion of important unanswered questions and likely future directions for the field over the next decade.

Published
2023
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13. First light from the MATS satellite

Author

Christensen, Ole Martin, primary, Gumbel, Jörg, additional, Megner, Linda, additional, Murtagh, Donal, additional, Linder, Björn, additional, Hedin, Jonas, additional, Ivchenko, Nickolay, additional, and Stegman, Jacek, additional

Published
2023
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16. The MAGIC meteoric smoke particle sampler

Author

Hedin, Jonas, Giovane, Frank, Waldemarsson, Tomas, Gumbel, Jörg, Blum, Jürgen, Stroud, Rhonda M., Marlin, Layne, Moser, John, Siskind, David E., Jansson, Kjell, Saunders, Russell W., Summers, Michael E., Reissaus, Philipp, Stegman, Jacek, Plane, John M.C., and Horányi, Mihály

Published
2014
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18. Comparison of middle- and low-latitude sodium layer from a\ud ground-based lidar network, the Odin satellite, and WACCM-Na\ud model

Author

Yu, Bingkun, Xue, Xianghui, Scott, Christopher J., Jia, Mingjiao, Feng, Wuhu, Plane, John M. C., Marsh, Daniel R., Hedin, Jonas, Gumbel, Jörg, and Dou, Xiankang

Abstract

The ground-based measurements obtained from a lidar network and the six-year OSIRIS limb-scanning radiance\ud measurements made by the Odin satellite are used to study the climatology of the middle- and low-latitude sodium (Na) layer. Up to January 2021, four Na resonance fluorescence lidars at Beijing (40.5◦N, 116.0◦E), Hefei (31.8◦N, 117.3◦E), Wuhan (30.5◦N, 114.4◦E), and Haikou (19.5◦N, 109.1◦E) collected vertical profiles of Na density for a total of 2,136 nights (19,587 h). These large datasets provide multi-year routine measurements of the Na layer with exceptionally high temporal and vertical resolution. The lidar measurements are particularly useful for filling in OSIRIS data gaps since the OSIRIS measurements were not made during the dark winter months because they utilise the solar-pumped resonance fluorescence from Na atoms. The observations of Na layers from the ground-based lidars and the satellite are comprehensively compared with a global model of meteoric Na in the atmosphere (WACCM-Na). The lidars present a unique test of OSIRIS and WACCM, because they cover the latitude range along 120◦E longitude in an unusual geographic location with significant gravity wave generation. In general, good agreement is found between lidar observations, satellite measurements, and WACCM simulations. Whereas the Na number density from OSIRIS is larger than that from the Na lidars at the four stations within one standard deviation of the OSIRIS monthly average, particularly in autumn and early winter arising from significant uncertainties in Na density retrieved from much less satellite radiance measurements. WACCM underestimates the seasonal variability of the Na layer observed at the lower latitude lidar stations (Wuhan and Haikou). This discrepancy suggests the seasonal variability of vertical constituent transport modeled in WACCM is underestimated because much of the gravity wave spectrum is not captured in the model.

Published
2022

21. Opinion: Recent Developments and Future Directions in Studying the Chemistry of the Mesosphere and Lower Thermosphere.

Author

Plane, John M. C., Gumbel, Jörg, Kalogerakis, Konstantinos S., Marsh, Daniel R., and von Savigny, Christian

Subjects
MESOSPHERE, ATMOSPHERIC physics, THERMOSPHERE, ATMOSPHERIC circulation, COSMIC dust, ICE clouds
Abstract

This Opinion article begins with a review of important advances in the science of the Mesosphere and Lower Thermosphere (MLT) region of the atmosphere that have occurred over the past two decades since the founding of Atmospheric Chemistry and Physics. The emphasis is on chemistry (although, of course, this cannot be decoupled from discussion of atmospheric physics and dynamics), and the primary focus is on work during the past 10 years. Topics that are covered include: observations (satellite, rocket and ground-based techniques); the variability and connectedness of the MLT on various length- and time-scales; airglow emissions; the cosmic dust input and meteoric metal layers; and noctilucent (or polar mesospheric) ice clouds. The paper then concludes with a discussion of important unanswered questions and likely future directions for the field over the next decade. [ABSTRACT FROM AUTHOR]

Published
2023
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25. Simultaneous in situ measurements of small-scale structures in neutral, plasma, and atomic oxygen densities during the WADIS sounding rocket project

Author

Strelnikov, Boris, Eberhart, Martin, Friedrich, Martin, Hedin, Jonas, Khaplanov, Mikhail, Baumgarten, Gerd, Williams, Bifford P., Staszak, Tristan, Asmus, Heiner, Strelnikova, Irina, Latteck, Ralph, Grygalashvyly, Mykhaylo, Lübken, Franz-Josef, Höffner, Josef, Wörl, Raimund, Gumbel, Jörg, Löhle, Stefan, Fasoulas, Stefanos, Rapp, Markus, Barjatya, Aroh, Taylor, Michael J., Pautet, Pierre-Dominique, and Copernicus GmbH

Subjects
thermosphere, lcsh:Chemistry, Astrophysics and Astronomy, chemical, lcsh:QD1-999, Physics::Space Physics, measurements, structures, plasma, lcsh:Physics, lcsh:QC1-999
Abstract

In this paper we present an overview of measurements conducted during the WADIS-2 rocket campaign. We investigate the effect of small-scale processes like gravity waves and turbulence on the distribution of atomic oxygen and other species in the mesosphere–lower thermosphere (MLT) region. Our analysis suggests that density fluctuations of atomic oxygen are coupled to fluctuations of other constituents, i.e., plasma and neutrals. Our measurements show that all measured quantities, including winds, densities, and temperatures, reveal signatures of both waves and turbulence. We show observations of gravity wave saturation and breakdown together with simultaneous measurements of generated turbulence. Atomic oxygen inside turbulence layers shows two different spectral behaviors, which might imply a change in its diffusion properties.

Published
2019

27. The MATS satellite mission - gravity wave studies by Mesospheric Airglow/Aerosol Tomography and Spectroscopy

Author

Gumbel, Jörg, Megner, Linda, Christensen, Ole Martin, Ivchenko, Nickolay, Murtagh, Donal P., Chang, Seunghyuk, Dillner, Joachim, Ekebrand, Terese, Giono, Gabriel, Hammar, Arvid, Hedin, Jonas, Karlsson, Bodil, Krus, Mikael, Li, Anqi, McCallion, Steven, Olentšenko, Georgi, Pak, Soojong, Park, Woojin, Rouse, Jordan, Stegman, Jacek, Witt, Georg, Gumbel, Jörg, Megner, Linda, Christensen, Ole Martin, Ivchenko, Nickolay, Murtagh, Donal P., Chang, Seunghyuk, Dillner, Joachim, Ekebrand, Terese, Giono, Gabriel, Hammar, Arvid, Hedin, Jonas, Karlsson, Bodil, Krus, Mikael, Li, Anqi, McCallion, Steven, Olentšenko, Georgi, Pak, Soojong, Park, Woojin, Rouse, Jordan, Stegman, Jacek, and Witt, Georg

Abstract

Global three-dimensional data are a key to understanding gravity waves in the mesosphere and lower thermosphere. MATS (Mesospheric Airglow/Aerosol Tomography and Spectroscopy) is a new Swedish satellite mission that addresses this need. It applies space-borne limb imaging in combination with tomographic and spectroscopic analysis to obtain gravity wave data on relevant spatial scales. Primary measurement targets are O-2 atmospheric band dayglow and nightglow in the near infrared, and sunlight scattered from noctilucent clouds in the ultraviolet. While tomography provides horizontally and vertically resolved data, spectroscopy allows analysis in terms of mesospheric temperature, composition, and cloud properties. Based on these dynamical tracers, MATS will produce a climatology on wave spectra during a 2-year mission. Major scientific objectives include a characterization of gravity waves and their interaction with larger-scale waves and mean flow in the mesosphere and lower thermosphere, as well as their relationship to dynamical conditions in the lower and upper atmosphere. MATS is currently being prepared to be ready for a launch in 2020. This paper provides an overview of scientific goals, measurement concepts, instruments, and analysis ideas.

Published
2020
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31. Comparison of middle- and low-latitude sodium layer from a ground-based lidar network, the Odin satellite, and WACCM-Na model.

Author

Bingkun Yu, Xianghui Xue, Scott, Christopher J., Mingjiao Jia, Wuhu Feng, Plane, John M. C., Marsh, Daniel R., Hedin, Jonas, Gumbel, Jörg, and Xiankang Dou

Subjects
LIDAR, RESONANCE, CLIMATOLOGY, STANDARD deviations, SOLAR energy
Abstract

The ground-based measurements obtained from a lidar network and the six-year OSIRIS limb-scanning radiance measurements made by the Odin satellite are used to study the climatology of the middle- and low-latitude sodium (Na) layer. Up to January 2021, four Na resonance fluorescence lidars at Beijing (40.2°N, 116.2°E), Hefei (31.8°N, 117.3°E), Wuhan (30.5°N, 114.4°E), and Haikou (19.5°N, 109.1°E) collected vertical profiles of Na density for a total of 2,136 nights (19,587 h). These large datasets provide routine long-term measurements of the Na layer with exceptionally high temporal and vertical resolution. The lidar measurements are particularly useful for filling in OSIRIS data gaps since the OSIRIS measurements were not made during the dark winter months because they utilise the solar-pumped resonance fluorescence from Na atoms. The observations of Na layers from the ground-based lidars and the satellite are comprehensively compared with a global model of meteoric Na in the atmosphere (WACCM-Na). The lidars present a unique test of OSIRIS and WACCM, because they cover the latitude range along 120°E longitude in an unusual geographic location with significant gravity wave generation. In general, good agreement is found between lidar observations, satellite measurements, and WACCM simulations. Whereas the Na number density from OSIRIS is slightly larger than that from the Na lidars at the four stations within one standard deviation of the OSIRIS monthly average, particularly in autumn and early winter arising from significant uncertainties in Na density retrieved from much less satellite radiance measurements. WACCM underestimates the seasonal variability of the Na layer observed at the lower latitude lidar stations (Wuhan and Haikou). This discrepancy suggests the seasonal variability of vertical constituent transport modeled in WACCM is underestimated because much of the gravity wave spectrum is not captured in the model. [ABSTRACT FROM AUTHOR]

Published
2022
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32. Comparison of middle- and low-latitude sodium layer from a ground-based lidar network, the Odin satellite, andWACCM-Na model.

Author

Bingkun Yu, Xianghui Xue, Scott, Christopher J., Mingjiao Jia, Wuhu Feng, Plane, John M. C., Marsh, Daniel R., Hedin, Jonas, Gumbel, Jörg, and Xiankang Dou

Abstract

The ground-based measurements obtained from a lidar network and the six-year OSIRIS limb-scanning radiance measurements made by the Odin satellite are used to study the climatology of the middle- and low-latitude sodium (Na) layer. Up to January 2021, four Na resonance fluorescence lidars at Beijing (40.2° N, 116.2° E), Hefei (31.8° N, 117.3° E), Wuhan (30.5° N, 114.4° E), and Haikou (19.5° N, 109.1° E) collected vertical profiles of Na density for a total of 2,136 nights (19,587 h). These large datasets provide routine long-term measurements of the Na layer with exceptionally high temporal and vertical resolution. The lidar measurements are particularly useful for filling in OSIRIS data gaps since the OSIRIS measurements were not made during the dark winter months because they utilise the solar-pumped resonance fluorescence from Na atoms. The observations of Na layers from the ground-based lidars and the satellite are comprehensively compared with a global model of meteoric Na in the atmosphere (WACCM-Na). The lidars present a unique test of OSIRIS and WACCM, because they cover the latitude range along 120° E longitude in an unusual geographic location with significant gravity wave generation. In general, good agreement is found between lidar observations, satellite measurements, and WACCM simulations. Whereas the Na number density from OSIRIS is slightly larger than that from the Na lidars at the four stations within one standard deviation of the OSIRIS monthly average, particularly in autumn and early winter arising from significant uncertainties in Na density retrieved from much less satellite radiance measurements. WACCM underestimates the seasonal variability of the Na layer observed at the lower latitude lidar stations (Wuhan and Haikou). This discrepancy suggests the seasonal variability of vertical constituent transport modeled in WACCM is underestimated because much of the gravity wave spectrum is not captured in the model. [ABSTRACT FROM AUTHOR]

Published
2022
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34. The MATS satellite mission – gravity wave studies by Mesospheric Airglow/Aerosol Tomography and Spectroscopy

Author

Gumbel, Jörg, primary, Megner, Linda, additional, Christensen, Ole Martin, additional, Ivchenko, Nickolay, additional, Murtagh, Donal P., additional, Chang, Seunghyuk, additional, Dillner, Joachim, additional, Ekebrand, Terese, additional, Giono, Gabriel, additional, Hammar, Arvid, additional, Hedin, Jonas, additional, Karlsson, Bodil, additional, Krus, Mikael, additional, Li, Anqi, additional, McCallion, Steven, additional, Olentšenko, Georgi, additional, Pak, Soojong, additional, Park, Woojin, additional, Rouse, Jordan, additional, Stegman, Jacek, additional, and Witt, Georg, additional

Published
2020
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35. Atomic oxygen number densities in the mesosphere–lower thermosphere region measured by solid electrolyte sensors on WADIS-2

Author

Eberhart, Martin, Löhle, Stefan, Strelnikov, Boris, Hedin, Jonas, Khaplanov, Mikhail, Fasoulas, Stefanos, Gumbel, Jörg, Lübken, Franz-Josef, and Rapp, Markus

Subjects
Institut für Physik der Atmosphäre, mesosphere-lower thermosphere, WADIS-2, atomic Oxygen
Abstract

Absolute profiles of atomic oxygen number densities with high vertical resolution have been determined in the mesosphere–lower thermosphere (MLT) region from in situ measurements by several rocket-borne solid electrolyte sensors. The amperometric sensors were operated in both controlled and uncontrolled modes and with various orientations on the foredeck and aft deck of the payload. Calibration was based on mass spectrometry in a molecular beam containing atomic oxygen produced in a microwave discharge. The sensor signal is proportional to the number flux onto the electrodes, and the mass flow rate in the molecular beam was additionally measured to derive this quantity from the spectrometer reading. Numerical simulations provided aerodynamic correction factors to derive the atmospheric number density of atomic oxygen from the sensor data. The flight results indicate a preferable orientation of the electrode surface perpendicular to the rocket axis. While unstable during the upleg, the density profiles measured by these sensors show an excellent agreement with the atmospheric models and photometer results during the downleg of the trajectory. The high spatial resolution of the measurements allows for the identification of small-scale variations in the atomic oxygen concentration.

Published
2019

36. Analysis of Particle Shape, Depolarization and Lidar Ratio in Arctic Cirrus Clouds: A Case Study

Author

Wolf, Veronika, Völger, Peter, Kuhn, Thomas, and Gumbel, Jörg

Subjects
Meteorology and Atmospheric Sciences, Meteorologi och atmosfärforskning, Physics::Atmospheric and Oceanic Physics
Abstract

Lidar measurements and balloon-borne in-situ measurements were performed concurrently in Kiruna, (Sweden) in order to study the influence of particle properties on lidar measurements. By comparing the extinction coefficient profiles determined with both methods, we find smaller depolarisation ratios and lidar ratios when small and compact particles dominate compared to situations with larger particlesand non-compact shapes.

Published
2019

37. Common volume satellite studies of polar mesospheric clouds with Odin/OSIRIS tomography and AIM/CIPS nadir imaging

Author

Broman, Lina, Benze, Susanne, Gumbel, Jörg, Christensen, Ole Martin, Randall, Cora E., Broman, Lina, Benze, Susanne, Gumbel, Jörg, Christensen, Ole Martin, and Randall, Cora E.

Abstract

Two important approaches for satellite studies of polar mesospheric clouds (PMCs) are nadir measurements adapting phase function analysis and limb measurements adapting spectroscopic analysis. Combining both approaches enables new studies of cloud structures and microphysical processes but is complicated by differences in scattering conditions, observation geometry and sensitivity. In this study, we compare common volume PMC observations from the nadir-viewing Cloud Imaging and Particle Size (CIPS) instrument on the Aeronomy of Ice in the Mesosphere (AIM) satellite and a special set of tomographic limb observations from the Optical Spectrograph and InfraRed Imager System (OSIRIS) on the Odin satellite performed over 18 d for the years 2010 and 2011 and the latitude range 78 to 80 degrees N. While CIPS provides preeminent horizontal resolution, the OSIRIS tomographic analysis provides combined horizontal and vertical PMC information. This first direct comparison is an important step towards co-analysing CIPS and OSIRIS data, aiming at unprecedented insights into horizontal and vertical cloud processes. Important scientific questions on how the PMC life cycle is affected by changes in humidity and temperature due to atmospheric gravity waves, planetary waves and tides can be addressed by combining PMC observations in multiple dimensions. Two- and three-dimensional cloud structures simultaneously observed by CIPS and tomographic OSIRIS provide a useful tool for studies of cloud growth and sublimation Moreover, the combined CIPS/tomographic OSIRIS dataset can be used for studies of even more fundamental character, such as the question of the assumption of the PMC particle size distribution. We perform the first thorough error characterization of OSIRIS tomographic cloud brightness and cloud ice water content (IWC). We establish a consistent method for comparing cloud properties from limb tomography and nadir observations, accounting for differences in scattering conditi

Published
2019
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38. Atmospheric band fitting coefficients derived from a self-consistent rocket-borne experiment

Author

Grygalashvyly, Mykhaylo, Eberhart, Martin, Hedin, Jonas, Strelnikov, Boris, Lübken, Franz-Josef, Rapp, Markus, Löhle, Stefan, Fasoulas, Stefanos, Khaplanova, Mikhail, Gumbel, Jörg, Vorobeva, Ekaterina, Grygalashvyly, Mykhaylo, Eberhart, Martin, Hedin, Jonas, Strelnikov, Boris, Lübken, Franz-Josef, Rapp, Markus, Löhle, Stefan, Fasoulas, Stefanos, Khaplanova, Mikhail, Gumbel, Jörg, and Vorobeva, Ekaterina

Abstract

Based on self-consistent rocket-borne measurements of temperature, the densities of atomic oxygen and neutral air, and the volume emission of the atmospheric band (762 nm), we examined the one-step and two-step excitation mechanism of O-2 (b(1)Sigma(+)(g)) for nighttime conditions. Following McDade et al. (1986), we derived the empirical fitting coefficients, which parameterize the atmospheric band emission O-2 (b(1)Sigma(+)(g) - X-3 Sigma(-)(g)) (0, 0). This allows us to derive the atomic oxygen concentration from nighttime observations of atmospheric band emission O-2 (b(1)Sigma(+)(g) - X-3 Sigma(-)(g)) (0, 0). The derived empirical parameters can also be utilized for atmospheric band modeling. Additionally, we derived the fit function and corresponding coefficients for the combined (one-and two-step) mechanism. The simultaneous common volume measurements of all the parameters involved in the theoretical calculation of the observed O-2 (b(1)Sigma(+)(g) - X-3 Sigma(-)(g)) (0, 0) emission, i.e., temperature and density of the background air, atomic oxygen density, and volume emission rate, is the novelty and the advantage of this work.

Published
2019
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42. Simultaneous in situ measurements of small-scale structures in neutral, plasma, and atomic oxygen densities during WADIS sounding rocket project

Author

Strelnikov, Boris, primary, Eberhart, Martin, additional, Friedrich, Martin, additional, Hedin, Jonas, additional, Khaplanov, Mikhail, additional, Baumgarten, Gerd, additional, Williams, Bifford P., additional, Staszak, Tristan, additional, Asmus, Heiner, additional, Strelnikova, Irina, additional, Latteck, Ralph, additional, Grygalashvyly, Mykhaylo, additional, Lübken, Franz-Josef, additional, Höffner, Josef, additional, Wörl, Raimund, additional, Gumbel, Jörg, additional, Löhle, Stefan, additional, Fasoulas, Stefanos, additional, Rapp, Markus, additional, Barjatya, Aroh, additional, Taylor, Michael J., additional, and Pautet, Pierre-Dominique, additional

Published
2019
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44. Spatial and temporal variability in MLT turbulence inferred from in situ and ground-based observations during the WADIS-1 sounding rocket campaign

Author

Strelnikov, Boris, Szewczyk, Artur, Strelnikova, Irina, Latteck, Ralph, Baumgarten, Gerd, Lübken, Franz-Josef, Rapp, Markus, Fasoulas, Stefanos, Löhle, Stefan, Eberhart, Martin, Hoppe, Ulf-Peter, Dunker, Tim, Friedrich, Martin, Hedin, Jonas, Khaplanov, Mikhail, Gumbel, Jörg, and Barjatya, Aroh

Subjects
Institut für Physik der Atmosphäre, VDP::Matematikk og Naturvitenskap: 400::Fysikk: 430, Physics::Space Physics, Physics::Atmospheric and Oceanic Physics, VDP::Mathematics and natural science: 400::Physics: 430, Meteorology and atmospheric dynamics (turbulence)
Abstract

In summer 2013 the WADIS-1 sounding rocket campaign was conducted at the Andøya Space Center (ACS) in northern Norway (69° N, 16° E). Among other things, it addressed the question of the variability in mesosphere/lower thermosphere (MLT) turbulence, both in time and space. A unique feature of the WADIS project was multi-point turbulence sounding applying different measurement techniques including rocket-borne ionization gauges, VHF MAARSY radar, and VHF EISCAT radar near Tromsø. This allowed for horizontal variability to be observed in the turbulence field in the MLT at scales from a few to 100 km. We found that the turbulence dissipation rate, ε varied in space in a wavelike manner both horizontally and in the vertical direction. This wavelike modulation reveals the same vertical wavelengths as those seen in gravity waves. We also found that the vertical mean value of radar observations of ε agrees reasonably with rocket-borne measurements. In this way defined 〈εradar〉 value reveals clear tidal modulation and results in variation by up to 2 orders of magnitude with periods of 24 h. The 〈εradar〉 value also shows 12 h and shorter (1 to a few hours) modulations resulting in one decade of variation in 〈εradar〉 magnitude. The 24 h modulation appeared to be in phase with tidal change of horizontal wind observed by SAURA-MF radar. Such wavelike and, in particular, tidal modulation of the turbulence dissipation field in the MLT region inferred from our analysis is a new finding of this work.

Published
2017

45. Comparison of In-Situ Balloon-Borne and Lidar Measurement of Cirrus Clouds

Author

Kuhn, Thomas, Wolf, Veronika, Völger, Peter, Stanev, Marin, and Gumbel, Jörg

Subjects
Rymd- och flygteknik, Arctic, in-situ, Cirrus, ice particles, high latitude measurements, Geovetenskap och miljövetenskap, balloon-borne, Aerospace Engineering, ice clouds, Earth and Related Environmental Sciences, lidar
Abstract

A series of in-situ balloon-borne experiments con- ducted at Kiruna, Sweden (68°N), is studying upper- tropospheric, cold ice clouds in arctic latitudes. Ex- periments are launched from Esrange Space Center and collect ice particles with an in-situ imaging instrument. One of the aims with these measurements is to improve satellite remote sensing of cold ice clouds. Such clouds can be observed by lidar. Therefore, when possible, concurrent ground-based lidar measurements have been carried out with two available lidar systems to accom- pany the balloon-borne measurements. The Esrange lidar is located at Esrange Space Center, approximately 500 m from the in-situ launch site on the balloon pad; the IRF lidar is located about 29 km to the west of Esrange Space Center (operated by the Swedish Institute of Space Physics, IRF). Here we present results from these lidar measurements and compare them to ice particle proper- ties determined during the in-situ measurements.

Published
2017

46. Making limb and nadir measurements comparable: A common volume study of PMC brightness observed by Odin OSIRIS and AIM CIPS

Author

Benze, Susanne, Gumbel, Jörg, Randall, Cora E., Karlsson, Bodil, Hultgren, Kristoffer, Lumpe, Jerry D., and Baumgarten, Gerd

Subjects
Common volume, CIPS, Nadir, OSIRIS, Limb, Polar mesospheric cloud
Abstract

Combining limb and nadir satellite observations of Polar Mesospheric Clouds (PMCs) has long been recognized as problematic due to differences in observation geometry, scattering conditions, and retrieval approaches. This study offers a method of comparing PMC brightness observations from the nadir-viewing Aeronomy of Ice in the Mesosphere (AIM) Cloud Imaging and Particle Size (CIPS) instrument and the limb-viewing Odin Optical Spectrograph and InfraRed Imaging System (OSIRIS). OSIRIS and CIPS measurements are made comparable by defining a common volume for overlapping OSIRIS and CIPS observations for two northern hemisphere (NH) PMC seasons: NH08 and NH09. We define a scattering intensity quantity that is suitable for either nadir or limb observations and for different scattering conditions. A known CIPS bias is applied, differences in instrument sensitivity are analyzed and taken into account, and effects of cloud inhomogeneity and common volume definition on the comparison are discussed. Not accounting for instrument sensitivity differences or inhomogeneities in the PMC field, the mean relative difference in cloud brightness (CIPS - OSIRIS) is −102 ± 55%. The differences are largest for coincidences with very inhomogeneous clouds that are dominated by pixels that CIPS reports as non-cloud points. Removing these coincidences, the mean relative difference in cloud brightness reduces to −6 ± 14%. The correlation coefficient between the CIPS and OSIRIS measurements of PMC brightness variations in space and time is remarkably high, at 0.94. Overall, the comparison shows excellent agreement despite different retrieval approaches and observation geometries.

Published
2017
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47. The MATS Satellite Mission – Gravity Waves Studies by Mesospheric Airglow/Aerosol Tomography and Spectroscopy

Author

Gumbel, Jörg, primary, Megner, Linda, additional, Christensen, Ole Martin, additional, Chang, Seunghyuk, additional, Dillner, Joachim, additional, Ekebrand, Terese, additional, Giono, Gabriel, additional, Hammar, Arvid, additional, Hedin, Jonas, additional, Ivchenko, Nickolay, additional, Karlsson, Bodil, additional, Kruse, Mikael, additional, Li, Anqi, additional, McCallion, Steven, additional, Murtagh, Donal P., additional, Olentšenko, Georgi, additional, Pak, Soojong, additional, Park, Woojin, additional, Rouse, Jordan, additional, Stegman, Jacek, additional, and Witt, Georg, additional

Published
2018
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