Analysis of atmospheric water vapor and related dynamic processes

Dans le contexte du réchauffement et du changement climatique, il est important d’étudier les distributions, les cycles saisonniers et les tendances des gaz à l’état de trace dans l’atmosphère tels que la vapeur d’eau. L'Observatoire de Physique du Globe de Clermont-Ferrand a en charge plusieurs dispositifs d’observation dont le site instrumenté Cézeaux, Opme et Puy de Dôme (CO-PDD) situés dans le centre de la France (45◦ N, 3◦ E). Le site des Cézeaux dispose d’un LIDAR Rayleigh – Mie - Raman fournissant en routine des profils verticaux de vapeur d’eau et de paramètres optiques caractérisant les cirrus. Le site du puy de Dôme est équipé d’un spectroscope à cavité optique (CRDS-Picarro). Des mesures de colonnes totales de vapeur d’eau sont disponibles sur tous ces sites par GPS. Le site d’Opme est équipé d’un pluviomètre. Enfin Météo-France effectue le travail de contrôle qualité des données météorologiques sur les stations de mesure en France et ces données ont été utilisées dans cette thèse. La validation des données sur le site du puy de Dôme a été la première la première exploitation dans cette thèse. Des comparaisons des données sur le puy de Dôme ont montré un très bon accord entre les données de vapeur d’eau extraites de la station météorologique du puy de Dôme, de Météo France et les donnes CRDS du puy de Dôme, avec une corrélation de 0.94 et 0.98 respectivement. Les profils verticaux obtenus par LIDAR ont permis de sélectionner une anomalie de vapeur d’eau et d’identifier une intrusion stratosphère-troposphère en analysant les processus dynamique associés à cette anomalie. Les données OLR ont montré que cette intrusion est accompagnée de convection profonde et enfin LACYTRAJ confirme l'origine stratosphérique d’une partie de la masse d'air présente au-dessus de Clermont-Ferrand au cours de l’anomalie. Les longues séries d’observations (ex : Puy de Dôme 1995-2015) et des ré-analyse ECMWF ERA-Interim (1979-2017) et la diversité des sources de données (ex : satellites AIRS et COSMIC), nous permettent de documenter, analyser et comparer la variabilité, les cycles et la tendance de la vapeur d'eau à la surface et dans la troposphère, à différentes échelles de temps et déterminer les processus géophysiques responsables des distributions de vapeur d'eau sur le site CO-PDD. Le cycle annuel de la vapeur d'eau est clairement établi pour les deux sites de différentes altitudes et pour tous les types de mesure. Les sites de Cézeaux et du puy de Dôme ne présentent presque aucun cycle diurne, suggérant que la variabilité de la vapeur d'eau à la surface sur ces deux sites est plus influencée par les systèmes météorologique sporadiques que par les variations diurnes régulières. Les données LIDAR montrent une plus grande variabilité mensuelle de la distribution verticale que les produits satellites COSMIC et AIRS. La colonne totale de vapeur d'eau GPS sur le site des Cézeaux présente une tendance positive (0,42 ± 0,45 g/kg*décade entre 2006-2017). L'analyse par régressions multi-linéaires montre que les forçages continentaux (East Atlantic, East Atlantic-West Russia) ont une plus grande influence que le forçage océanique (Nord Atlantic Oscillation) sur les variations de vapeur d'eau.In the context of global warming and climate change, it is important to study the distributions, seasonal cycles and trends of trace gases in the atmosphere such as water vapor. of the Observatoire de Physique du Globe de Clermont-Ferrand is in charge of several observation devices including the instrumented site Cézeaux, Opme and Puy de Dôme (CO-PDD) located near the center of France (45◦ N, 3◦ E). The site of Cézeaux is instrumented by a Rayleigh - Mie–LIDAR Raman providing routine vertical profiles of water vapor mixing ratio and optical parameters characterizing cirrus clouds. The puy de Dôme site is equipped with an optical cavity spectroscope (CRDS-Picarro). Measurements of total water vapor columns are available on all these sites by GPS. The Opme site is equipped with rain gauges. Finally, Météo-France performs the quality control work and of data on meteorological stations in France and these data were used in this thesis. The validation of the puy de Dôme data was the first the first task in this thesis. Comparisons between the puy de Dôme data sets showed a very good agreement between the water vapor datafrom the OPGC meteorological station of Puy de Dôme, Météo France and CRDS data with a correlation of 0.94 and 0.98 respectively. The vertical profiles deduced from the LIDAR allowed to identify a water vapor anomaly and a stratosphere-troposphere intrusion associated with this anomaly. OLR data showed that this intrusion could be linked with deep convection and LACYTRAJ confirms the stratospheric origin of a part of the air mass present above Clermont-Ferrand. Long series of observations (eg Puy de Dôme 1995-2015) and ECMWF ERA-Interim re-analysis (1979-2017) and the diversity of data sources (eg AIRS and COSMIC satellites), allowed us to document, analyze and compare the variability, cycles and trend of surface and tropospheric water vapor at different time scales and determine the geophysical processes responsible for water vapor distributions at the site of CO-PDD. The annual cycle of water vapor is clearly established for the two sites of different altitudes and for all types of measurement. Cézeaux and puy de Dôme present almost no diurnal cycle, suggesting that the variability of surface water vapor at this site is more influenced by a sporadic meteorological system than by regular diurnal variations. The LIDAR dataset shows a greater monthly variability of the vertical distribution than the COSMIC and AIRS satellite products. The Cézeaux site presents a positive trend for the GPS water vapor total column (0.42 ± 0.45 g/kg*decade during 2006–2017) and a significant negative trend for the surface water vapor mixing ratio (−0.16 ± 0.09 mm/decade during 2002–2017). The multi-linear regression analysis shows that continental forcings (East Atlantic Pattern and East Atlantic-West Russia Pattern) have a larger influence than oceanic forcing (North Atlantic Oscillation) on the water vapor variations

Analyse de la vapeur d’eau atmosphérique et des processus dynamiques associés

In the context of global warming and climate change, it is important to study the distributions, seasonal cycles and trends of trace gases in the atmosphere such as water vapor. of the Observatoire de Physique du Globe de Clermont-Ferrand is in charge of several observation devices including the instrumented site Cézeaux, Opme and Puy de Dôme (CO-PDD) located near the center of France (45◦ N, 3◦ E). The site of Cézeaux is instrumented by a Rayleigh - Mie–LIDAR Raman providing routine vertical profiles of water vapor mixing ratio and optical parameters characterizing cirrus clouds. The puy de Dôme site is equipped with an optical cavity spectroscope (CRDS-Picarro). Measurements of total water vapor columns are available on all these sites by GPS. The Opme site is equipped with rain gauges. Finally, Météo-France performs the quality control work and of data on meteorological stations in France and these data were used in this thesis. The validation of the puy de Dôme data was the first the first task in this thesis. Comparisons between the puy de Dôme data sets showed a very good agreement between the water vapor datafrom the OPGC meteorological station of Puy de Dôme, Météo France and CRDS data with a correlation of 0.94 and 0.98 respectively. The vertical profiles deduced from the LIDAR allowed to identify a water vapor anomaly and a stratosphere-troposphere intrusion associated with this anomaly. OLR data showed that this intrusion could be linked with deep convection and LACYTRAJ confirms the stratospheric origin of a part of the air mass present above Clermont-Ferrand. Long series of observations (eg Puy de Dôme 1995-2015) and ECMWF ERA-Interim re-analysis (1979-2017) and the diversity of data sources (eg AIRS and COSMIC satellites), allowed us to document, analyze and compare the variability, cycles and trend of surface and tropospheric water vapor at different time scales and determine the geophysical processes responsible for water vapor distributions at the site of CO-PDD. The annual cycle of water vapor is clearly established for the two sites of different altitudes and for all types of measurement. Cézeaux and puy de Dôme present almost no diurnal cycle, suggesting that the variability of surface water vapor at this site is more influenced by a sporadic meteorological system than by regular diurnal variations. The LIDAR dataset shows a greater monthly variability of the vertical distribution than the COSMIC and AIRS satellite products. The Cézeaux site presents a positive trend for the GPS water vapor total column (0.42 ± 0.45 g/kg*decade during 2006–2017) and a significant negative trend for the surface water vapor mixing ratio (−0.16 ± 0.09 mm/decade during 2002–2017). The multi-linear regression analysis shows that continental forcings (East Atlantic Pattern and East Atlantic-West Russia Pattern) have a larger influence than oceanic forcing (North Atlantic Oscillation) on the water vapor variations.Dans le contexte du réchauffement et du changement climatique, il est important d’étudier les distributions, les cycles saisonniers et les tendances des gaz à l’état de trace dans l’atmosphère tels que la vapeur d’eau. L'Observatoire de Physique du Globe de Clermont-Ferrand a en charge plusieurs dispositifs d’observation dont le site instrumenté Cézeaux, Opme et Puy de Dôme (CO-PDD) situés dans le centre de la France (45◦ N, 3◦ E). Le site des Cézeaux dispose d’un LIDAR Rayleigh – Mie - Raman fournissant en routine des profils verticaux de vapeur d’eau et de paramètres optiques caractérisant les cirrus. Le site du puy de Dôme est équipé d’un spectroscope à cavité optique (CRDS-Picarro). Des mesures de colonnes totales de vapeur d’eau sont disponibles sur tous ces sites par GPS. Le site d’Opme est équipé d’un pluviomètre. Enfin Météo-France effectue le travail de contrôle qualité des données météorologiques sur les stations de mesure en France et ces données ont été utilisées dans cette thèse. La validation des données sur le site du puy de Dôme a été la première la première exploitation dans cette thèse. Des comparaisons des données sur le puy de Dôme ont montré un très bon accord entre les données de vapeur d’eau extraites de la station météorologique du puy de Dôme, de Météo France et les donnes CRDS du puy de Dôme, avec une corrélation de 0.94 et 0.98 respectivement. Les profils verticaux obtenus par LIDAR ont permis de sélectionner une anomalie de vapeur d’eau et d’identifier une intrusion stratosphère-troposphère en analysant les processus dynamique associés à cette anomalie. Les données OLR ont montré que cette intrusion est accompagnée de convection profonde et enfin LACYTRAJ confirme l'origine stratosphérique d’une partie de la masse d'air présente au-dessus de Clermont-Ferrand au cours de l’anomalie. Les longues séries d’observations (ex : Puy de Dôme 1995-2015) et des ré-analyse ECMWF ERA-Interim (1979-2017) et la diversité des sources de données (ex : satellites AIRS et COSMIC), nous permettent de documenter, analyser et comparer la variabilité, les cycles et la tendance de la vapeur d'eau à la surface et dans la troposphère, à différentes échelles de temps et déterminer les processus géophysiques responsables des distributions de vapeur d'eau sur le site CO-PDD. Le cycle annuel de la vapeur d'eau est clairement établi pour les deux sites de différentes altitudes et pour tous les types de mesure. Les sites de Cézeaux et du puy de Dôme ne présentent presque aucun cycle diurne, suggérant que la variabilité de la vapeur d'eau à la surface sur ces deux sites est plus influencée par les systèmes météorologique sporadiques que par les variations diurnes régulières. Les données LIDAR montrent une plus grande variabilité mensuelle de la distribution verticale que les produits satellites COSMIC et AIRS. La colonne totale de vapeur d'eau GPS sur le site des Cézeaux présente une tendance positive (0,42 ± 0,45 g/kg*décade entre 2006-2017). L'analyse par régressions multi-linéaires montre que les forçages continentaux (East Atlantic, East Atlantic-West Russia) ont une plus grande influence que le forçage océanique (Nord Atlantic Oscillation) sur les variations de vapeur d'eau

Midpalatal suture: evaluation of the morphological maturation stages via bone density

Abstract Background To investigate the relationship between the morphological maturation stages of the midpalatal suture and its bone densities. Methods The sample consisted of 91 subjects aged 8–18 years who underwent cone beam computed tomography. All images were examined to classify morphological maturation of the midpalatal suture to five groups according to Angelieri et al. Bone density of the midpalatal suture was measured at the maxillary and palatal regions. Kruskal-Wallis and Mann-Whitney U tests were used to analyze the difference between groups. Results Bone density of the midpalatal suture was significantly higher in the palatal region in E stage and in the maxillary region in D and E stages. Conclusions It is concluded that the change in bone density of the midpalatal suture between the morphological maturation stages supports their reliability in clinical application

A Predictive Decision Approach for Firefighters Using Variable Selection Technique

International audienceFirefighters are using empirical approaches to manage their human resources for covering the daily interventions. With data digitization, many data are incremental available and could be treated for prognostic purposes. Prognostics and health management could be an efficient way to provide a help in the decision-making for firefighter interventions. We hence have an access to a data set of the number of interventions of firefighters in the Bourgogne Franche-Comt\'e region of eastern France. The aim of this paper is to propose a variable selection technique for firefighters interventions prediction. For that purpose, we estimate the contribution of each variable on the number of interventions for selecting major variables and show their impact on intervention prediction. The proposed model is applied on a case study, where a efficient variables selection is obtained for prediction

Seasonal Variation of Aerosol Size Distribution Data at the Puy de Dôme Station with Emphasis on the Boundary Layer/Free Troposphere Segregation

International audienceAerosol particles are important due to their direct and indirect impacts on climate. Within the planetary boundary layer (BL), these particles have a relatively short lifetime due to their frequent removal process by wet deposition. When aerosols are transported into the free troposphere (FT), their atmospheric lifetime increases significantly, making them representative of large spatial areas. In this work, we use a combination of in situ measurements performed at the high altitude PUY (Puy de Dôme, 45 • 46 N, 2 • 57 E, 1465 m a.s.l) station, together with LIDAR profiles at Clermont-Ferrand for characterizing FT conditions, and further characterize the physical properties of aerosol in this poorly documented area of the atmosphere. First, a combination of four criteria was used to identify whether the PUY station lies within the FT or within the BL. Results show that the PUY station is located in BL with frequencies ranging from 50% during the winter, up to 97% during the summer. Then, the classification is applied to a year-long dataset (2015) of particle size distribution data to study the differences in particle physical characteristics (size distribution) and black carbon (BC) concentrations between the FT and the BL. Although BC, Aitken, and the accumulation mode particles concentrations were higher in the BL than in the FT in winter and autumn, they were measured to be higher in the FT compared to BL in spring. No significant difference between the BL and the FT concentrations was observed for the nucleation mode particles for all seasons, suggesting a continuous additional source of nucleation mode particles in the FT during winter and autumn. Coarse mode particle concentrations were found higher in the FT than in the BL for all seasons and especially during summer. This indicates an efficient long-range transport of large particles in the FT from distant sources (marine and desert) due to higher wind speeds in the FT compared to BL. For FT air masses, we used 204-h air mass back-trajectories combined with boundary layer height estimations from ECMWF ERA-Interim to assess the time they spent in the FT since their last contact with the BL and to evaluate the impact of this parameter on the aerosol properties. We observed that even after 75 h without any contact with the BL, FT aerosols preserve specific properties of their air mass type

Surface and Tropospheric Water Vapor Variability and Decadal Trends at Two Supersites of CO-PDD (Cézeaux and Puy de Dôme) in Central France

International audienceWe present an analysis of decadal in situ and remote sensing observations of water vapor over the Cézeaux and puy de Dôme, located in central France (45 • N, 3 • E), in order to document the variability, cycles and trends of surface and tropospheric water vapor at different time scales and the geophysical processes responsible for the water vapor distributions. We use meteorological stations, GPS (Global Positioning System), and lidar datasets, supplemented with three remote sources of water vapor (COSMIC-radio-occultation, ERA-interim-ECMWF numerical model, and AIRS-satellite). The annual cycle of water vapor is clearly established for the two sites of different altitudes and for all types of measurement. Cezeaux and puy de Dôme present almost no diurnal cycle, suggesting that the variability of surface water vapor at this site is more influenced by a sporadic meteorological system than by regular diurnal variations. The lidar dataset shows a greater monthly variability of the vertical distribution than the COSMIC and AIRS satellite products. The Cézeaux site presents a positive trend for the GPS water vapor total column (0.42 ± 0.45 g·kg −1 /decade during 2006-2017) and a significant negative trend for the surface water vapor mixing ratio (−0.16 ± 0.09 mm/decade during 2002-2017). The multi-linear regression analysis shows that continental forcings (East Atlantic Pattern and East Atlantic-West Russia Pattern) have a greater influence than oceanic forcing (North Atlantic Oscillation) on the water vapor variations

Autosomal-Recessive Hypophosphatemic Rickets Is Associated with an Inactivation Mutation in the ENPP1 Gene

Human disorders of phosphate (Pi) handling and hypophosphatemic rickets have been shown to result from mutations in PHEX, FGF23, and DMP1, presenting as X-linked recessive, autosomal-dominant, and autosomal-recessive patterns, respectively. We present the identification of an inactivating mutation in the ecto-nucleotide pyrophosphatase/phosphodiesterase 1 (ENPP1) gene causing autosomal-recessive hypophosphatemic rickets (ARHR) with phosphaturia by positional cloning. ENPP1 generates inorganic pyrophosphate (PPi), an essential physiologic inhibitor of calcification, and previously described inactivating mutations in this gene were shown to cause aberrant ectopic calcification disorders, whereas no aberrant calcifications were present in our patients. Our surprising result suggests a different pathway involved in the generation of ARHR and possible additional functions for ENPP1