Your search keyword '"R. Dragani"' showing total 14 results

1. Application of the Complete Data Fusion algorithm to the ozone profiles measured by geostationary and low-Earth-orbit satellites: a feasibility study

Author

N. Zoppetti, S. Ceccherini, B. Carli, S. Del Bianco, M. Gai, C. Tirelli, F. Barbara, R. Dragani, A. Arola, J. Kujanpää, J. C. A. van Peet, R. van der A, and U. Cortesi

Subjects

Environmental engineering, TA170-171, Earthwork. Foundations, TA715-787

Abstract

The new platforms for Earth observation from space are characterized by measurements made at great spatial and temporal resolutions. While this abundance of information makes it possible to detect and study localized phenomena, it may be difficult to manage this large amount of data for the study of global and large-scale phenomena. A particularly significant example is the use by assimilation systems of Level 2 products that represent gas profiles in the atmosphere. The models on which assimilation systems are based are discretized on spatial grids with horizontal dimensions of the order of tens of kilometres in which tens or hundreds of measurements may fall in the future. A simple procedure to overcome this problem is to extract a subset of the original measurements, but this involves a loss of information. Another option is the use of simple averages of the profiles, but this approach also has some limitations that we will discuss in the paper. A more advanced solution is to resort to the so-called fusion algorithms, capable of compressing the size of the dataset while limiting the information loss. A novel data fusion method, the Complete Data Fusion algorithm, was recently developed to merge a set of retrieved products in a single product a posteriori. In the present paper, we apply the Complete Data Fusion method to ozone profile measurements simulated in the thermal infrared and ultraviolet bands in a realistic scenario. Following this, the fused products are compared with the input profiles; comparisons show that the output products of data fusion have smaller total errors and higher information contents in general. The comparisons of the fused products with the fusing products are presented both at single fusion grid box scale and with a statistical analysis of the results obtained on large sets of fusion grid boxes of the same size. We also evaluate the grid box size impact, showing that the Complete Data Fusion method can be used with different grid box sizes even if this possibility is connected to the natural variability of the considered atmospheric molecule.

Published

2021

2. Temperature and tropopause characteristics from reanalyses data in the tropical tropopause layer

Author

S. Tegtmeier, J. Anstey, S. Davis, R. Dragani, Y. Harada, I. Ivanciu, R. Pilch Kedzierski, K. Krüger, B. Legras, C. Long, J. S. Wang, K. Wargan, and J. S. Wright

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The tropical tropopause layer (TTL) is the transition region between the well-mixed convective troposphere and the radiatively controlled stratosphere with air masses showing chemical and dynamical properties of both regions. The representation of the TTL in meteorological reanalysis data sets is important for studying the complex interactions of circulation, convection, trace gases, clouds, and radiation. In this paper, we present the evaluation of climatological and long-term TTL temperature and tropopause characteristics in the reanalysis data sets ERA-Interim, ERA5, JRA-25, JRA-55, MERRA, MERRA-2, NCEP-NCAR (R1), and CFSR. The evaluation has been performed as part of the SPARC (Stratosphere–troposphere Processes and their Role in Climate) Reanalysis Intercomparison Project (S-RIP). The most recent atmospheric reanalysis data sets (ERA-Interim, ERA5, JRA-55, MERRA-2, and CFSR) all provide realistic representations of the major characteristics of the temperature structure within the TTL. There is good agreement between reanalysis estimates of tropical mean temperatures and radio occultation data, with relatively small cold biases for most data sets. Temperatures at the cold point and lapse rate tropopause levels, on the other hand, show warm biases in reanalyses when compared to observations. This tropopause-level warm bias is related to the vertical resolution of the reanalysis data, with the smallest bias found for data sets with the highest vertical resolution around the tropopause. Differences in the cold point temperature maximize over equatorial Africa, related to Kelvin wave activity and associated disturbances in TTL temperatures. Interannual variability in reanalysis temperatures is best constrained in the upper TTL, with larger differences at levels below the cold point. The reanalyses reproduce the temperature responses to major dynamical and radiative signals such as volcanic eruptions and the quasi-biennial oscillation (QBO). Long-term reanalysis trends in temperature in the upper TTL show good agreement with trends derived from adjusted radiosonde data sets indicating significant stratospheric cooling of around −0.5 to −1 K per decade. At 100 hPa and the cold point, most of the reanalyses suggest small but significant cooling trends of −0.3 to −0.6 K per decade that are statistically consistent with trends based on the adjusted radiosonde data sets. Advances of the reanalysis and observational systems over the last decades have led to a clear improvement in the TTL reanalysis products over time. Biases of the temperature profiles and differences in interannual variability clearly decreased in 2006, when densely sampled radio occultation data started being assimilated by the reanalyses. While there is an overall good agreement, different reanalyses offer different advantages in the TTL such as realistic profile and cold point temperature, continuous time series, or a realistic representation of signals of interannual variability. Their use in model simulations and in comparisons with climate model output should be tailored to their specific strengths and weaknesses.

Published

2020

3. Importance of interpolation and coincidence errors in data fusion

Author

S. Ceccherini, B. Carli, C. Tirelli, N. Zoppetti, S. Del Bianco, U. Cortesi, J. Kujanpää, and R. Dragani

Subjects

Environmental engineering, TA170-171, Earthwork. Foundations, TA715-787

Abstract

The complete data fusion (CDF) method is applied to ozone profiles obtained from simulated measurements in the ultraviolet and in the thermal infrared in the framework of the Sentinel 4 mission of the Copernicus programme. We observe that the quality of the fused products is degraded when the fusing profiles are either retrieved on different vertical grids or referred to different true profiles. To address this shortcoming, a generalization of the complete data fusion method, which takes into account interpolation and coincidence errors, is presented. This upgrade overcomes the encountered problems and provides products of good quality when the fusing profiles are both retrieved on different vertical grids and referred to different true profiles. The impact of the interpolation and coincidence errors on number of degrees of freedom and errors of the fused profile is also analysed. The approach developed here to account for the interpolation and coincidence errors can also be followed to include other error components, such as forward model errors.

Published

2018

4. Assessment of upper tropospheric and stratospheric water vapor and ozone in reanalyses as part of S-RIP

Author

S. M. Davis, M. I. Hegglin, M. Fujiwara, R. Dragani, Y. Harada, C. Kobayashi, C. Long, G. L. Manney, E. R. Nash, G. L. Potter, S. Tegtmeier, T. Wang, K. Wargan, and J. S. Wright

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Reanalysis data sets are widely used to understand atmospheric processes and past variability, and are often used to stand in as "observations" for comparisons with climate model output. Because of the central role of water vapor (WV) and ozone (O3) in climate change, it is important to understand how accurately and consistently these species are represented in existing global reanalyses. In this paper, we present the results of WV and O3 intercomparisons that have been performed as part of the SPARC (Stratosphere–troposphere Processes and their Role in Climate) Reanalysis Intercomparison Project (S-RIP). The comparisons cover a range of timescales and evaluate both inter-reanalysis and observation-reanalysis differences. We also provide a systematic documentation of the treatment of WV and O3 in current reanalyses to aid future research and guide the interpretation of differences amongst reanalysis fields.The assimilation of total column ozone (TCO) observations in newer reanalyses results in realistic representations of TCO in reanalyses except when data coverage is lacking, such as during polar night. The vertical distribution of ozone is also relatively well represented in the stratosphere in reanalyses, particularly given the relatively weak constraints on ozone vertical structure provided by most assimilated observations and the simplistic representations of ozone photochemical processes in most of the reanalysis forecast models. However, significant biases in the vertical distribution of ozone are found in the upper troposphere and lower stratosphere in all reanalyses.In contrast to O3, reanalysis estimates of stratospheric WV are not directly constrained by assimilated data. Observations of atmospheric humidity are typically used only in the troposphere, below a specified vertical level at or near the tropopause. The fidelity of reanalysis stratospheric WV products is therefore mainly dependent on the reanalyses' representation of the physical drivers that influence stratospheric WV, such as temperatures in the tropical tropopause layer, methane oxidation, and the stratospheric overturning circulation. The lack of assimilated observations and known deficiencies in the representation of stratospheric transport in reanalyses result in much poorer agreement amongst observational and reanalysis estimates of stratospheric WV. Hence, stratospheric WV products from the current generation of reanalyses should generally not be used in scientific studies.

Published

2017

5. Introduction to the SPARC Reanalysis Intercomparison Project (S-RIP) and overview of the reanalysis systems

Author

M. Fujiwara, J. S. Wright, G. L. Manney, L. J. Gray, J. Anstey, T. Birner, S. Davis, E. P. Gerber, V. L. Harvey, M. I. Hegglin, C. R. Homeyer, J. A. Knox, K. Krüger, A. Lambert, C. S. Long, P. Martineau, A. Molod, B. M. Monge-Sanz, M. L. Santee, S. Tegtmeier, S. Chabrillat, D. G. H. Tan, D. R. Jackson, S. Polavarapu, G. P. Compo, R. Dragani, W. Ebisuzaki, Y. Harada, C. Kobayashi, W. McCarty, K. Onogi, S. Pawson, A. Simmons, K. Wargan, J. S. Whitaker, and C.-Z. Zou

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The climate research community uses atmospheric reanalysis data sets to understand a wide range of processes and variability in the atmosphere, yet different reanalyses may give very different results for the same diagnostics. The Stratosphere–troposphere Processes And their Role in Climate (SPARC) Reanalysis Intercomparison Project (S-RIP) is a coordinated activity to compare reanalysis data sets using a variety of key diagnostics. The objectives of this project are to identify differences among reanalyses and understand their underlying causes, to provide guidance on appropriate usage of various reanalysis products in scientific studies, particularly those of relevance to SPARC, and to contribute to future improvements in the reanalysis products by establishing collaborative links between reanalysis centres and data users. The project focuses predominantly on differences among reanalyses, although studies that include operational analyses and studies comparing reanalyses with observations are also included when appropriate. The emphasis is on diagnostics of the upper troposphere, stratosphere, and lower mesosphere. This paper summarizes the motivation and goals of the S-RIP activity and extensively reviews key technical aspects of the reanalysis data sets that are the focus of this activity. The special issue The SPARC Reanalysis Intercomparison Project (S-RIP) in this journal serves to collect research with relevance to the S-RIP in preparation for the publication of the planned two (interim and full) S-RIP reports.

Published

2017

6. A comparative analysis of UV nadir-backscatter and infrared limb-emission ozone data assimilation

Author

R. Dragani

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper presents a comparative assessment of ultraviolet nadir-backscatter and infrared limb-emission ozone profile assimilation. The Meteorological Operational Satellite A (MetOp-A) Global Ozone Monitoring Experiment 2 (GOME-2) nadir and the ENVISAT Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) limb profiles, generated by the ozone consortium of the European Space Agency Climate Change Initiative (ESA O3-CCI), were individually added to a reference set of ozone observations and assimilated in the European Centre for Medium-Range Weather Forecasts (ECMWF) data assimilation system (DAS). The two sets of resulting analyses were compared with that from a control experiment, only constrained by the reference dataset, and independent, unassimilated observations. Comparisons with independent observations show that both datasets improve the stratospheric ozone distribution. The changes inferred by the limb-based observations are more localized and, in places, more important than those implied by the nadir profiles, albeit they have a much lower number of observations. A small degradation (up to 0.25 mg kg−1 for GOME-2 and 0.5 mg kg−1 for MIPAS in the mass mixing ratio) is found in the tropics between 20 and 30 hPa. In the lowermost troposphere below its vertical coverage, the limb data are found to be able to modify the ozone distribution with changes as large as 60 %. Comparisons of the ozone analyses with sonde data show that at those levels the assimilation of GOME-2 leads to about 1 Dobson Unit (DU) smaller root mean square error (RMSE) than that of MIPAS. However, the assimilation of MIPAS can still improve the quality of the ozone analyses and – with a reduction in the RMSE of up to about 2 DU – outperform the control experiment thanks to its synergistic assimilation with total-column ozone data within the DAS. High vertical resolution ozone profile observations are essential to accurately monitor and forecast ozone concentrations in a DAS. This study demonstrates the potential and limitations of each dataset and instrument type, as well as the need for a balanced future availability of nadir and limb sensors and long-term plans for limb-viewing instruments.

Published

2016

7. AURORA Project: Main Achievements from Science, through Technology, to Applications

Author

U. Cortesi, C. Tirelli, S. Ceccherini, S. Del Bianco, M.Gai, N. Zoppetti, F. Barbara, R. Dragani, R. van der A, J. van Peet, O. Tuinder, A. Arola, A. Lipponen, J. Kujanpaa, W. Wandji, A. Keppens, M. van Roezendael, J-C. Lambert, A. Masini, E. Simeone, B. Canessa, E. Loenen, A. Bos, M. Bonazountas, A. Argyridis, and K. Verberne

Subjects

Ultraviolet radiation, Ozone, Data sinergy, Atmospheric Sentinel, Copernicus

Abstract

A substantial leap in our capability to monitor atmospheric composition from space is taking place with the new generation of satellite missions devoted to the study of air quality, climate change, stratospheric ozone and UV radiation reaching the Earth's surface. The need to meet increasingly demanding observation requirements is leading to the deployment of space-borne instruments offering groundbreaking levels of performance. Moreover, the growing number of payloads on board already operating or planned low Earth orbit and geostationary platforms is making complementary information available on a wealth of key targets retrieved from observations at different frequencies and with different viewing geometries. Optimal exploitation of the information contained in temporally and spatially collocated datasets from multiple measurement sources is, therefore, the key opportunity and challenge characterizing this novel scenario. In the context of the Horizon 2020 framework program of the European Union, the AURORA (Advanced Ultraviolet Radiation and Ozone Retrieval for Applications) project was precisely designed to respond to this quest by investigating the potential of synergistic use of independent measurements of an atmospheric variable by sequential application of an innovative data fusion method and data assimilation systems. The focus of the study has been on the vertical distribution of atmospheric Ozone for more than one reason. On the one hand, Ozone is a key atmospheric compound playing different roles at different altitudes; on the other, being observable in several bands of the spectrum, is among the trace gases that can mostly benefit of data synergy. The investigation was conducted using simulated data of the atmospheric Sentinel missions of the Copernicus Program (i.e., Ultraviolet and Visible measurements of the UVN and UVNS spectrometers of Sentinel-4 and Sentinel-5, respectively, as well as Thermal Infrared observations of IASI-NG on MSG and IRS on MTG). The presentation will describe the main achievements of the project: oby retracing the journey across the scientific challenges of the design and implementation of the AURORA data processing chain; oby highlighting the need to realize a technological infrastructure capable to run the end-to-end process from the inputs of synthetic Ozone data by multiple sources to the output a unique Ozone profile estimate; oby illustrating the outcome of application-oriented activities intended to demonstrate the use of tropospheric ozone and UV surface radiation products calculated in AURORA in new applications for air quality monitoring and forecasting at urban scale and for personal UV dosimetry, respectively.

Published

2019

8. The AURORA project: ScientificDevelopmentsand Results

Author

R. Dragani, S. Quesada Ruiz, S.Ceccherini, S. Del Bianco, M. Gai, C. Tirelli, N. Zoppetti, A. Arola, J. Kujanpää, W. Wandji, A. Lipponen, R. van der A, J. Van Peet, O. Tuinder, A. Keppens, M. VanRoozendael, J-C. Lambert, Xiong Liu, Chris Miller, Juseon Bak, and U. Cortesi

Subjects

Ozone, Data synergy, Ultraviolet Radiation, Sentinel-5, Sentinel-4, Data Assimilation, Data Fusion, Copernicus

Abstract

The Advanced Ultraviolet Radiation and Ozone Retrieval for Applications (AURORA) is a three-year project supported by the European Union during the 2016-2019 period. The main goal of AURORA is to develop and test the coupling of a data fusion algorithm with state-of-the-art data assimilation systems in an end-to-end infrastructure that could be used as prototype for the exploitation of future Copernicus Sentinel-4 (S4) and Sentinel-5 (S5) atmospheric data. A simplified Observing System Simulated Experiment approach has been adopted in the project. Using MERRA-2 reanalysis as virtual truth, synthetic measurements have been generated to simulate the future S4 and S5 data in three spectral ranges (i.e. Ultraviolet, Visible and Thermal Infrared). Level 2 ozone products have then been derived for both platforms and the three spectral ranges. A data fusion technique, referred to as the Complete Data Fusion (CDF), has been applied as an a-posteriori method to combine the Level-2 products into a comprehensive and concise description of that atmospheric state. Both the Level-2 and fused ozone products have been assimilated in two state-of-the-art data assimilation systems: the ECMWF IFS and KNMI TM5. An incremental assimilation experiment design has been defined to assess the potential value of (1) assimilating fused data instead of the Level-2 retrievals, (2) using fused data from one geostationary platform in addition to polar orbiting-based fused data, and (3) exploiting cross-platform fused data instead of jointly assimilating fused products from multiple platforms. A collaboration with the American TEMPO and Korean GEMS geostationary satellite communities has been established in the AURORA project with the aim of evaluating the value of increasing the geostationary coverage from one (S4 only) to three. Off-line tropospheric ozone and surface UV products are also generated from the data assimilation ozone analyses and forecasts. A validation function has been developed to assess the quality of all the AURORA outputs against both independent observations and the MERRA-2 reanalysis used to derive the simulated measurements. This contribution will present the scientific developments undertaken within the AURORA project, and summarize its results.

Published

2019

9. Advanced tropospheric ozone monitoring by data fusion and assimilation

Author

C. Tirelli, U.Cortesi, S. Del Bianco, S. Ceccherini, N. Zoppetti, R. Dragani, M. Bonazountas, C. Tsiakos, E. Simeone, A. Keppens, J-C. Lambert, M. van Roezendael, J. van Peet, R. van der A, E. Loenen, K. Verberne, A. Arola, and J. Kujanpaa

Subjects

Ozone, Data assimilation, Sentinel 4, Data fusion, Sentinel 5

Abstract

Ozone is a significant greenhouse gas that is formed and destroyed by chemical reactions involving other species in the atmosphere and a key constituent for understanding the interactions between climate and chemistry. In contrast to most GHGs, tropospheric ozone is produced photo-chemically via its precursors, notably nitrogen oxides, carbon monoxide, CH4 and non-methane hydrocarbons, all of which have large anthropogenic sources. Crucial uncertainties however remain in the assessment of the tropospheric ozone budget, its precursors, and the chemical and physical processes involved. Large spatial and temporal variability is observed in tropospheric ozone, resulting from important regional differences in the factors controlling its concentration. For all these reasons, accurate global measurements of ozone vertical profiles are essential. Instruments developed over recent decades to monitor ozone from space exploit a large range of observation geometries and spectral regions. However, due to the inherent limitations of each space-borne measurement technique, none of the existing systems can cover the needs for accurate ozone observations from the surface up to the mesosphere. AURORA (Advanced Ultraviolet Radiation and Ozone Retrieval for Applications) is a three-year project supported by the European Union in the frame of its H2020 Call EO-2-2015 with the overarching objective to simulate the provision of synergistic data products, having unprecedented accuracy, for the vertical profiling of atmospheric ozone and to assess their quality with respect to the one expected for the operational products of the geostationary (GEO) mission Sentinel-4 and of the Low Earth Orbit (LEO) missions Sentinel-5p and Sentinel-5. The main scientific purpose of AURORA is to investigate the potential of synergistic exploitation of complementary measurements of ozone acquired in different spectral regions - from the UV over the visible to the thermal infrared - through the assimilation of fused GEO and LEO ozone profile products resulting from application of an innovative data fusion method. The impact of combining complementary capabilities of the atmospheric Sentinels observations, especially in terms of vertical sensitivity, might result in advanced performances that are of specific relevance for tropospheric ozone monitoring. An extensive ozone product validation system is being developed in the frame of the project to assure that the AURORA ozone profile and tropospheric ozone data products will be warily verified and documented by means of thorough QA/validation studies. In a longer term perspective, demonstration of successful application of the AURORA concept to ozone might foster further scientific and technological developments towards exploitation of this innovative approach for other GHGs monitoring.

Published

2017

10. AURORA Project: Advanced Ultraviolet Radiation and Ozone Retrieval for Applications

Author

U.Cortesi, S. Del Bianco, M.Gai, S. Ceccherini, C. Tirelli, M. Bonazountas, S. Kalogridis, A. Trypitsidis, A. Bos, E. Zoutman, E. Loenen, A. Arola, J. Kujanpaa, W. Wandji, R. van der A, J. van Peet, M. Morelli, A. Masini, E. Simeone, R. Dragani, A. Keppens, J-C. Lambert, M. van Roezendael, C. Lerot, and K. Verberne

Subjects

Ozone, Data assimilation, Sentinel 4, Data fusion, Sentinel 5

Abstract

AURORA is a three years project supported by the European Union after evaluation of the proposal submitted in response to the call EO-2-2015 "Stimulating wider research use of Copernicus Sentinel Data" of the subprogramme Space in the frame of the Horizon 2020 framework programme. The primary goal of AURORA is to exploit the complementary measurement capabilities of the instruments on board the Sentinel-4 and Sentinel-5 missions of Copernicus, operating on Low Earth Orbit (LEO) and on Geostationary Orbit (GEO) respectively, for near real-time monitoring of the ozone vertical profile with unprecedented accuracy. All the activities of the project will be conducted by using simulated data of Sentinel-4 and Sentinel-5. Innovative scientific approaches and technological solutions will be applied to derive a unique geophysical product from the operational ozone data from independent datasets simultaneously acquired by observing the same air masses in different spectral regions and viewing geometries. New data fusion techniques will combine the information associated to the operational products of the LEO instruments, as well as to the ones oF the GEO mission. The fused ozone profiles will be merged into assimilation models, to integrate in particular the combined LEO and GEO products in a short-term ozone-forecasting model. Specific focus of the project will be on the lowermost atmospheric layers to derive ozone partial column values (e.g., lower tropospheric column) and UV radiation reaching the Earth's surface. A dedicated technological infrastructure, exploiting virtual machine and cloud data sharing, will be created to implement the data processing chain, including a geo-database and web services for data access. The AURORA infrastructure aims to guarantee the most user-friendly access to the output products, indeed to stimulate a wider use of the huge amount of data, which we expect to become available with the atmospheric Sentinels. This first priority purpose will be pursued, in fact, by developing two downstream applications based on the AURORA data products; for personal UV dosimetry and for providing air quality information in major cities and improving air quality prediction at regional scale.

Published

2016

11. The GlobMODEL Demonstrator: Assimilation of New Satellite Products in an Operational Meteorological Center

Author

Alan O'Neill, Roger Brugge, Jean-Noël Thépaut, A.K. Kaiser-Weiss, Stefano Migliorini, and R. Dragani

Subjects

Ozone Monitoring Instrument, Atmospheric Science, Ozone, Meteorology, Differential optical absorption spectroscopy, SCIAMACHY, chemistry.chemical_compound, Data assimilation, chemistry, Ozone layer, Environmental science, Satellite, Computers in Earth Sciences, Stratosphere

Abstract

As part of its Data User Element programme, the European Space Agency funded the GlobMODEL project which aimed at investigating the scientific, technical, and organizational issues associated with the use and exploitation of remotely-sensed observations, particularly from new sounders. A pilot study was performed as a ldquodemonstratorrdquo of the GlobMODEL idea, based on the use of new data, with a strong European heritage, not yet assimilated operationally. Two parallel assimilation experiments were performed, using either total column ozone or ozone profiles retrieved at the Royal Netherlands Meteorological Institute (KNMI) from the Ozone Monitoring Instrument (OMI). In both cases, the impact of assimilating OMI data in addition to the total ozone columns from the SCanning Imaging Absorption spectroMeter for Atmospheric CartograpHY (SCIAMACHY) on the European Centre for Medium Range Weather Forecasts (ECMWF) ozone analyses was assessed by means of independent measurements. We found that the impact of OMI total columns is mainly limited to the region between 20 and 80 hPa, and is particularly important at high latitudes in the Southern hemisphere where the stratospheric ozone transport and chemical depletion are generally difficult to model with accuracy. Furthermore, the assimilation experiments carried out in this work suggest that OMI DOAS (Differential Optical Absorption Spectroscopy) total ozone columns are on average larger than SCIAMACHY total columns by up to 3 DU, while OMI total columns derived from OMI ozone profiles are on average about 8 DU larger than SCIAMACHY total columns. At the same time, the demonstrator brought to light a number of issues related to the assimilation of atmospheric composition profiles, such as the shortcomings arising when the vertical resolution of the instrument is not properly accounted for in the assimilation. The GlobMODEL demonstrator accelerated scientific and operational utilization of new observations and its results prompted ECMWF to start the operational assimilation of OMI total column ozone data.

Published

2009

12. Etude d'un amortisseur avec des butees et du frottement non-lineaire

Author

M. Sarra and R. Dragani

Subjects

Physics, Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics, Civil and Structural Engineering

Published

1981

13. Influence of Viscous-Coulomb damping on a system with stops

Author

R. Dragani and A. Répaci

Subjects

Physics, Coulomb damping, Mechanics of Materials, Mechanical Engineering, General Materials Science, Mechanics, Condensed Matter Physics, Civil and Structural Engineering

Published

1979

14. Assessment of upper tropospheric and stratospheric water vapor and ozone in reanalyses as part of S-RIP.

Author

Davis SM, Hegglin MI, Fujiwara M, Dragani R, Harada Y, Kobayashi C, Long C, Manney GL, Nash ER, Potter GL, Tegtmeier S, Wang T, Wargan K, and Wright JS

Abstract

Reanalysis data sets are widely used to understand atmospheric processes and past variability, and are often used to stand in as "observations" for comparisons with climate model output. Because of the central role of water vapor (WV) and ozone (O 3 ) in climate change, it is important to understand how accurately and consistently these species are represented in existing global reanalyses. In this paper, we present the results of WV and O 3 intercomparisons that have been performed as part of the SPARC (Stratosphere-troposphere Processes and their Role in Climate) Reanalysis Intercomparison Project (S-RIP). The comparisons cover a range of timescales and evaluate both inter-reanalysis and observation-reanalysis differences. We also provide a systematic documentation of the treatment of WV and O 3 in current reanalyses to aid future research and guide the interpretation of differences amongst reanalysis fields. The assimilation of total column ozone (TCO) observations in newer reanalyses results in realistic representations of TCO in reanalyses except when data coverage is lacking, such as during polar night. The vertical distribution of ozone is also relatively well represented in the stratosphere in reanalyses, particularly given the relatively weak constraints on ozone vertical structure provided by most assimilated observations and the simplistic representations of ozone photochemical processes in most of the reanalysis forecast models. However, significant biases in the vertical distribution of ozone are found in the upper troposphere and lower stratosphere in all reanalyses. In contrast to O 3 , reanalysis estimates of stratospheric WV are not directly constrained by assimilated data. Observations of atmospheric humidity are typically used only in the troposphere, below a specified vertical level at or near the tropopause. The fidelity of reanalysis stratospheric WV products is therefore mainly dependent on the reanalyses' representation of the physical drivers that influence stratospheric WV, such as temperatures in the tropical tropopause layer, methane oxidation, and the stratospheric overturning circulation. The lack of assimilated observations and known deficiencies in the representation of stratospheric transport in reanalyses result in much poorer agreement amongst observational and reanalysis estimates of stratospheric WV. Hence, stratospheric WV products from the current generation of reanalyses should generally not be used in scientific studies.

Published

2017