Filip Vanhellemont
Belgian Institute for Space Aeronomy
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Featured researches published by Filip Vanhellemont.
Advances in Space Research | 2004
E. Kyrölä; J. Tamminen; G.W. Leppelmeier; V. F. Sofieva; S. Hassinen; J. L. Bertaux; Alain Hauchecorne; Francis Dalaudier; C. Cot; Oleg Korablev; O. Fanton d’Andon; G. Barrot; A. Mangin; Bertrand Theodore; M. Guirlet; F. Etanchaud; P. Snoeij; R. Koopman; L. Saavedra; R. Fraisse; Didier Fussen; Filip Vanhellemont
Abstract GOMOS (Global Ozone Monitoring by Occultation of Stars) on board Envisat measures O 3 , NO 2 , NO 3 , neutral density, aerosols, H 2 O, and O 2 , in the stratosphere and mesosphere by detecting absorption of starlight in ultraviolet, visible and near-infrared wavelengths. During bright limb conditions GOMOS will also observe scattered solar radiation. GOMOS will deliver ozone concentration profiles at altitudes 15–100 km with a vertical sampling better than 1.7 km and with a global coverage. As a self-calibrating method stellar occultation measurements provide a basis for a long-term global monitoring of ozone profiles. We will present here the status of the GOMOS instrument and show samples of first results obtained in 2002.
Reviews of Geophysics | 2016
Stefanie Kremser; Larry W. Thomason; Marc von Hobe; Markus Hermann; Terry Deshler; Claudia Timmreck; Matthew Toohey; Andrea Stenke; Joshua P. Schwarz; R. Weigel; S. Fueglistaler; Fred Prata; Jean-Paul Vernier; Hans Schlager; John E. Barnes; Juan-Carlos Antuña-Marrero; Duncan Fairlie; Mathias Palm; Emmanuel Mahieu; Justus Notholt; Markus Rex; Christine Bingen; Filip Vanhellemont; John M. C. Plane; Daniel Klocke; Simon A. Carn; Lieven Clarisse; Thomas Trickl; Ryan R. Neely; Alexander D. James
Interest in stratospheric aerosol and its role in climate have increased over the last decade due to the observed increase in stratospheric aerosol since 2000 and the potential for changes in the sulfur cycle induced by climate change. This review provides an overview about the advances in stratospheric aerosol research since the last comprehensive assessment of stratospheric aerosol was published in 2006. A crucial development since 2006 is the substantial improvement in the agreement between in situ and space-based inferences of stratospheric aerosol properties during volcanically quiescent periods. Furthermore, new measurement systems and techniques, both in situ and space based, have been developed for measuring physical aerosol properties with greater accuracy and for characterizing aerosol composition. However, these changes induce challenges to constructing a long-term stratospheric aerosol climatology. Currently, changes in stratospheric aerosol levels less than 20% cannot be confidently quantified. The volcanic signals tend to mask any nonvolcanically driven change, making them difficult to understand. While the role of carbonyl sulfide as a substantial and relatively constant source of stratospheric sulfur has been confirmed by new observations and model simulations, large uncertainties remain with respect to the contribution from anthropogenic sulfur dioxide emissions. New evidence has been provided that stratospheric aerosol can also contain small amounts of nonsulfate matter such as black carbon and organics. Chemistry-climate models have substantially increased in quantity and sophistication. In many models the implementation of stratospheric aerosol processes is coupled to radiation and/or stratospheric chemistry modules to account for relevant feedback processes.
Journal of Geophysical Research | 2006
E. Kyrölä; J. Tamminen; G.W. Leppelmeier; V. F. Sofieva; S. Hassinen; Annika Seppälä; Pekka T. Verronen; J. L. Bertaux; Alain Hauchecorne; Francis Dalaudier; Didier Fussen; Filip Vanhellemont; O. Fanton d'Andon; G. Barrot; A. Mangin; Bertrand Theodore; M. Guirlet; R. Koopman; L. Saavedra de Miguel; P. Snoeij; Thorsten Fehr; Y. Meijer; R. Fraisse
[1] The Global Ozone Monitoring by Occultation of Stars (GOMOS) instrument on board the European Space Agency’s Envisat satellite measures ozone and a few other trace gases using the stellar occultation method. Global coverage, good vertical resolution and the self-calibrating measurement method make GOMOS observations a promising data set for building various climatologies. In this paper we present the nighttime stratospheric ozone distribution measured by GOMOS in 2003. We show monthly latitudinal distributions of the ozone number density and mixing ratio profiles, as well as the seasonal variations of profiles at several latitudes. The stratospheric profiles are compared with the Fortuin-Kelder daytime ozone climatology. Large differences are found in polar areas and they can be shown to be correlated with large increases of NO2. In the upper stratosphere, ozone values from GOMOS are systematically larger than in the Fortuin-Kelder climatology, which can be explained by the diurnal variation. In the middle and lower stratosphere, GOMOS finds a few percent less ozone than Fortuin-Kelder. In the equatorial area, at heights of around 15–22 km, GOMOS finds much less ozone than Fortuin-Kelder. For the mesosphere and lower thermosphere, there has previously been no comprehensive nighttime ozone climatology. GOMOS is one of the first new instruments able to contribute to such a climatology. We concentrate on the characterization of the ozone distribution in this region. The monthly latitudinal and seasonal distributions of ozone profiles in this altitude region are shown. The altitude of the mesospheric ozone peak and the semiannual oscillation of the number density are determined. GOMOS is also able to determine the magnitude of the ozone minimum around 80 km. The lowest seasonal mean mixing ratio values are around 0.13 ppm. The faint tertiary ozone peak at 72 km in polar regions during wintertime is observed.
Journal of Geophysical Research | 2005
Alain Hauchecorne; J. L. Bertaux; Francis Dalaudier; C. Cot; Jean-Claude Lebrun; Slimane Bekki; Marion Marchand; E. Kyrölä; J. Tamminen; V. F. Sofieva; Didier Fussen; Filip Vanhellemont; O. Fanton d'Andon; G. Barrot; A. Mangin; Bertrand Theodore; M. Guirlet; P. Snoeij; R. Koopman; L. Saavedra de Miguel; R. Fraisse; Jean-Baptiste Renard
The Global Ozone Monitoring by Occultation of Stars (GOMOS) stellar occultation instrument on board the Envisat European satellite provides global coverage of ozone and other stratospheric species with good vertical resolution and a self-calibrating method. In this paper we present the first simultaneous global distribution of stratospheric NO 2 and NO 3 from 1 year of nighttime GOMOS data in 2003. Most previous NO 2 satellite observations have been made using the solar occultation technique. They are difficult to interpret due to the fast photochemical evolution of NO 2 at sunrise and sunset. There are no published observations of NO 3 from space because this constituent is rapidly photodissociated during daytime and is not observable by solar occultation. It is shown that the NO 2 mixing ratio reaches a maximum around 40 km with values between 14 and 16 ppbv at low and middle latitudes. The global distribution of NO 2 observed by GOMOS is very similar to the NO + NO 2 Halogen Occultation Experiment climatology deduced from sunset measurements from 1999 to 2004. At high latitude a high mixing ratio is observed in the north vortex in November 2003 after a strong solar proton event and in the south vortex in July 2003. The NO 3 mixing ratio peaks at 40–45 km. NO 3 follows a semiannual variation at low latitudes with maxima at equinoxes and an annual variation at middle and high latitudes with a maximum in summer. In the upper stratosphere the mixing ratio of NO 3 is strongly correlated with temperature due to the thermal dependence of its formation rate. Citation: Hauchecorne, A., et al. (2005), First simultaneous global measurements of nighttime stratospheric NO 2 and NO 3 observed by Global Ozone Monitoring by Occultation of Stars (GOMOS)/Envisat in 2003
Atmospheric Chemistry and Physics | 2010
Didier Fussen; Filip Vanhellemont; C. Tétard; N. Mateshvili; Emmanuel Dekemper; Nicolas Loodts; Christine Bingen; E. Kyrölä; J. Tamminen; V. F. Sofieva; Alain Hauchecorne; Francis Dalaudier; G. Barrot; Laurent Blanot; O. Fanton d'Andon; Thorsten Fehr; L. Saavedra; T. Yuan; C.-Y. She
This paper presents a climatology of the mesospheric sodium layer built from the processing of 7 years of GOMOS data. With respect to preliminary results already published for the year 2003, a more careful analysis was applied to the averaging of occultations inside the climatological bins (10 in latitude-1 month). Also, the slant path absorption lines of the Na doublet around 589 nm shows evidence of partial saturation that was responsible for an underestimation of the Na concentration in our previous results. The sodium climatology has been validated with respect to the Fort Collins lidar measurements and, to a lesser extent, to the OSIRIS 2003–2004 data. Despite the important natural sodium variability, we have shown that the Na vertical column has a marked semi-annual oscillation at low latitudes that merges into an annual oscillation in the polar regions,a spatial distribution pattern that was unreported so far. The sodium layer seems to be clearly influenced by the mesospheric global circulation and the altitude of the layer shows clear signs of subsidence during polar winter. The climatology has been parameterized by time-latitude robust fits to alCorrespondence to: D. Fussen ([email protected]) low for easy use. Taking into account the non-linearity of the transmittance due to partial saturation, an experimental approach is proposed to derive mesospheric temperatures from limb remote sounding measurements.
Applied Optics | 2012
Emmanuel Dekemper; Nicolas Loodts; Bert Van Opstal; Jeroen Maes; Filip Vanhellemont; N. Mateshvili; Ghislain R. Franssens; Didier Pieroux; Christine Bingen; Charles Robert; Lieve De Vos; Ludovic Aballea; Didier Fussen
We describe a new spectral imaging instrument using a TeO(2) acousto-optical tunable filter (AOTF) operating in the visible domain (450-900 nm). It allows for fast (~1 second), monochromatic (FWHM ranges from 0.6 nm at 450 nm to 3.5 nm at 800 nm) picture acquisition with good spatial resolution. This instrument was designed as a breadboard of the visible channel of a new satellite-borne atmospheric limb spectral imager, named the Atmospheric Limb Tracker for the Investigation of the Upcoming Stratosphere (ALTIUS), that is currently being developed. We tested its remote sensing capabilities by observing the dense, turbulent plume exhausted by a waste incinerator stack at two wavelengths sensitive to NO(2). An average value of 6.0±0.4×10(17) molecules cm(-2) has been obtained for the NO(2) slant column density within the plume, close to the stack outlet. Although this result was obtained with a rather low accuracy, it demonstrates the potential of spectral imaging by using AOTFs in remote sensing.
Geophysical Research Letters | 2004
Didier Fussen; Filip Vanhellemont; Christine Bingen; E. Kyrölä; J. Tamminen; V. F. Sofieva; S. Hassinen; Annika Seppälä; Pekka T. Verronen; Alain Hauchecorne; Francis Dalaudier; Jean-Baptiste Renard; R. Fraisse; O. Fanton d'Andon; G. Barrot; A. Mangin; Bertrand Theodore; M. Guirlet; R. Koopman; Paul Snoeij; L. Saavedra
We present the first global measurement of the sodium mesospheric layer obtained from the processing of about 100 000 star occultations by the GOMOS instrument onboard the ENVISAT satellite. The retrieval method is developed on the basis of a simple DOAS retrieval applied to averaged transmittances. The vertical inversion of the sodium slant path optical thickness is performed by using a modified Gaussian extinction profile. A global climatology is derived by using monthly bins of 20 degrees in latitude. The high variability of the sodium layer is confirmed on a global scale as well as the presence of an important modulation in the annual cycle. Also, we present some evidence for the existence of a diurnal cycle characterized by an increase of the sodium concentration in daylight.
Geophysical Research Letters | 2007
V. F. Sofieva; E. Kyrölä; S. Hassinen; Leif Backman; J. Tamminen; Annika Seppälä; L. Thölix; A. S. Gurvich; V. Kan; Francis Dalaudier; Alain Hauchecorne; J. L. Bertaux; Didier Fussen; Filip Vanhellemont; O. Fanton d’Andon; G. Barrot; A. Mangin; M. Guirlet; Thorsten Fehr; P. Snoeij; L. Saavedra; R. Koopman; R. Fraisse
Stellar scintillations observed through the Earth atmosphere are caused by air density irregularities generated mainly by internal gravity waves and turbulence. We present global analysis of scintillation variance in two seasons of year 2003 based on GOMOS/Envisat fast photometer measurements. Scintillation variance can serve as a qualitative indicator of intensity of small-scale processes in the stratosphere. Strong increase of scintillation variance at high latitudes in winter is observed. The maximum of scintillation variance can be associated with the polar night jet. The simplified spectral analysis has shown the transition of scintillation spectra toward small scales with altitude, which is probably related with turbulence appearing as a result of wave breaking. The breaking of gravity waves in the polar night jet seems to start in the upper stratosphere, a predicted, but not confirmed by observations before, feature. Weaker enhancements in tropics are also observed; they might be related to tropical convection.
Atmospheric Environment | 2001
Didier Fussen; Filip Vanhellemont; Christine Bingen
Abstract This paper presents particle size distributions of stratospheric aerosols derived from solar occultation data measured by the instrument ORA (an acronym for Occultation RAdiometer) during the period August 1992–May 1993. Starting from the UV-visible wavelength dependence of extinction coefficient profiles, an algorithm is developed that allows to retrieve the three parameters of an equivalent log-normal distribution and that makes use of vertical regularization. Comparison of retrieved mode radius and particle number density with existing data is found to be satisfactory. The evolution of the stratospheric aerosols is clearly influenced by sedimentation and coagulation as expected but also by vertical circulation. In a simple 1-D model, we derive the vertical wind profile and we interpret the temporal evolution of the particle mode radius.
Applied Optics | 2001
Didier Fussen; Filip Vanhellemont; Christine Bingen
We describe the final inversion algorithm developed to process solar occultation data measured in 1992-1993 by the Occultation Radiometer (ORA) spaceborne experiment. First we develop a new method to improve the ORA total extinction altitude profiles retrieved with the previously described Natural Orthogonal Polynomial Expansion (NOPE) method. Using these improved profiles, we perform spectral inversion and obtain altitude density profiles for O(3) and NO(2) and extinction profiles for the aerosols. Validation of number density profiles between the Stratospheric Aerosol and Gas Experiment II (SAGE II) and the ORA shows satisfactory agreement.