78 research outputs found
A review of the Match technique as applied to AASE-2/EASOE and SOLVE/THESEO 2000
International audienceWe apply the NASA Goddard Trajectory Model to data from a series of ozonesondes to derive ozone loss rates in the lower stratosphere for the AASE-2/EASOE mission (January-March 1992) and for the SOLVE/THESEO 2000 mission (January-March 2000) in an approach similar to Match. Ozone loss rates are computed by comparing the ozone concentrations provided by ozonesondes launched at the beginning and end of the trajectories connecting the launches. We investigate the sensitivity of the Match results to the various parameters used to reject potential matches in the original Match technique. While these filters effectively eliminate from consideration 80% of the matched sonde pairs and >99% of matched observations in our study, we conclude that only a filter based on potential vorticity changes along the calculated back trajectories seems warranted. Our study also demonstrates that the ozone loss rates estimated in Match can vary by up to a factor of two depending upon the precise trajectory paths calculated for each trajectory. As a result, the statistical uncertainties published with previous Match results might need to be augmented by an additional systematic error. The sensitivity to the trajectory path is particularly pronounced in the month of January, for which the largest ozone loss rate discrepancies between photochemical models and Match are found. For most of the two study periods, our ozone loss rates agree with those previously published. Notable exceptions are found for January 1992 at 475K and late February/early March 2000 at 450K, both periods during which we generally find smaller loss rates than the previous Match studies. Integrated ozone loss rates estimated by Match in both of those years compare well with those found in numerous other studies and in a potential vorticity/potential temperature approach shown previously and in this paper. Finally, we suggest an alternate approach to Match using trajectory mapping. This approach uses information from all matched observations without filtering and uses a two-parameter fit to the data to produce robust ozone loss rate estimates. As compared to loss rates from our version of Match, the trajectory mapping approach produces generally smaller loss rates, frequently not statistically significantly different from zero, calling into question the efficacy of the Match approach
A global climatology of total columnar water vapour from SSM/I and MERIS
A global time series of total columnar water vapour from combined data of the
Medium Resolution Imaging Spectrometer (MERIS) onboard ESA's Environmental
Satellite (ENVISAT) and the Special Sensor Microwave/Imager (SSM/I) onboard
the satellite series of the US Defense Meteorological Satellite Program (DMSP)
is presented. The unique data set, generated in the framework of the ESA Data
User Element (DUE) GlobVapour project, combines atmospheric water vapour
observations over land and ocean, derived from measurements in the near-
infrared and the microwave range, respectively. Daily composites and monthly
means of total columnar water vapour are available as global maps on
rectangular latitude–longitude grids with a spatial resolution of 0.05° ×
0.05° over land and 0.5° × 0.5° over ocean for the years 2003 to 2008. The
data are stored in NetCDF files and is fully compliant with the NetCDF Climate
Forecast convention. Through the combination of high-quality microwave
observations and near-infrared observations over ocean and land surfaces,
respectively, the data set provides global coverage. The combination of both
products is carried out such that the individual properties of the microwave
and near-infrared products, in particular their uncertainties, are not
modified by the merging process and are therefore well defined. Due to the
global coverage and the provided uncertainty estimates this data set is
potentially of high value for climate research. The SSM/I-MERIS TCWV data set
is freely available via the GlobVapour project web page (www.globvapour.info)
with associated doi:10.5676/DFE/WV_COMB/FP. In this paper, the details of the
data set generation, i.e. the satellite data used, the retrieval techniques
and merging approaches, are presented. The derived level 3 products are
compared to global radiosonde data from the GCOS upper air network (GUAN),
showing a high agreement with a root-mean-square deviation of roughly 4.4 kg
m−2 and a small wet bias well below 1 kg m−2. Furthermore, the data set is
shown to be free of seasonal biases. The consistency of the MERIS and SSM/I
retrievals is demonstrated by applying the MERIS retrieval to sun glint areas
over ocean
A global climatology of total columnar water vapour from SSM/I and MERIS
A global time series of total columnar water vapour from combined data of the
Medium Resolution Imaging Spectrometer (MERIS) onboard ESA's Environmental
Satellite (ENVISAT) and the Special Sensor Microwave/Imager (SSM/I) onboard
the satellite series of the US Defense Meteorological Satellite Program (DMSP)
is presented. The unique data set, generated in the framework of the ESA Data
User Element (DUE) GlobVapour project, combines atmospheric water vapour
observations over land and ocean, derived from measurements in the near-
infrared and the microwave range, respectively. Daily composites and monthly
means of total columnar water vapour are available as global maps on
rectangular latitude–longitude grids with a spatial resolution of 0.05° ×
0.05° over land and 0.5° × 0.5° over ocean for the years 2003 to 2008. The
data are stored in NetCDF files and is fully compliant with the NetCDF Climate
Forecast convention. Through the combination of high-quality microwave
observations and near-infrared observations over ocean and land surfaces,
respectively, the data set provides global coverage. The combination of both
products is carried out such that the individual properties of the microwave
and near-infrared products, in particular their uncertainties, are not
modified by the merging process and are therefore well defined. Due to the
global coverage and the provided uncertainty estimates this data set is
potentially of high value for climate research. The SSM/I-MERIS TCWV data set
is freely available via the GlobVapour project web page (www.globvapour.info)
with associated doi:10.5676/DFE/WV_COMB/FP. In this paper, the details of the
data set generation, i.e. the satellite data used, the retrieval techniques
and merging approaches, are presented. The derived level 3 products are
compared to global radiosonde data from the GCOS upper air network (GUAN),
showing a high agreement with a root-mean-square deviation of roughly 4.4 kg
m−2 and a small wet bias well below 1 kg m−2. Furthermore, the data set is
shown to be free of seasonal biases. The consistency of the MERIS and SSM/I
retrievals is demonstrated by applying the MERIS retrieval to sun glint areas
over ocean
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Intercomparison Methods for Satellite Measurements of Atmospheric Composition: Application to Tropospheric Ozone from TES and OMI
We analyze the theoretical basis of three different methods to validate and intercompare satellite measurements of atmospheric composition, and apply them to tropospheric ozone retrievals from the Tropospheric Emission Spectrometer (TES) and the Ozone Monitoring Instrument (OMI). The first method (in situ method) uses in situ vertical profiles for absolute instrument validation; it is limited by the sparseness of in situ data. The second method (CTM method) uses a chemical transport model (CTM) as an intercomparison platform; it provides a globally complete intercomparison with relatively small noise from model error. The third method (averaging kernel smoothing method) involves smoothing the retrieved profile from one instrument with the averaging kernel matrix of the other; it also provides a global intercomparison but dampens the actual difference between instruments and adds noise from the a priori. We apply the three methods to a full year (2006) of TES and OMI data. Comparison with in situ data from ozonesondes shows mean positive biases of 5.3 parts per billion volume (ppbv) (10%) for TES and 2.8 ppbv (5%) for OMI at 500 hPa. We show that the CTM method (using the GEOS-Chem CTM) closely approximates results from the in situ method while providing global coverage. It reveals that differences between TES and OMI are generally less than 10 ppbv (18%), except at northern mid-latitudes in summer and over tropical continents. The CTM method further allows for CTM evaluation using both satellite observations. We thus find that GEOS-Chem underestimates tropospheric ozone in the tropics due to possible underestimates of biomass burning, soil, and lightning emissions. It overestimates ozone in the northern subtropics and southern mid-latitudes, likely because of excessive stratospheric influx of ozone.Earth and Planetary SciencesEngineering and Applied Science
Comparison of OMI ozone and UV irradiance data with ground-based measurements at two French sites
International audienceOzone Monitoring Instrument (OMI), launched in July 2004, is dedicated to the monitoring of the Earth's ozone, air quality and climate. OMI provides among other things the total column of ozone (TOC), the surface ultraviolet (UV) irradiance at several wavelengths, the erythemal dose rate and the erythemal daily dose. The main objective of this work is to validate OMI data with ground-based instruments in order to use OMI products (collection 2) for scientific studies. The Laboratoire d'Optique Atmosphérique (LOA) located in Villeneuve d'Ascq in the north of France performs solar UV measurements using a spectroradiometer and a broadband radiometer. The site of Briançon in the French Southern Alps is also equipped with a spectroradiometer operated by Interaction Rayonnement Solaire Atmosphère (IRSA). The instrument belongs to the Centre Européen Médical et Bioclimatologique de Recherche et d'Enseignement Supérieur. The comparison between the TOC retrieved with ground-based measurements and OMI TOC shows good agreement at both sites for all sky conditions. Comparisons of spectral UV on clear sky conditions are also satisfying whereas results of comparisons of the erythemal daily doses and erythemal dose rates for all sky conditions and for clear sky show that OMI overestimates significantly surface UV doses at both sites
Refrigerated warehouses as intelligent hubs to integrate renewable energy in industrial food refrigeration and to enhance power grid sustainability
© 2016 Elsevier LtdBackground Independence from fossil fuels, energy diversification, decarbonisation and energy efficiency are key prerequisites to make a national, regional or continental economy competitive in the global marketplace. As Europe is about to generate 20% of its energy demand from Renewable Energy Sources (RES) by 2020, adequate RES integration and renewable energy storage throughout the entire food cold chain must properly be addressed. Scope and approach Refrigerated warehouses for chilled and frozen foods are large energy consumers and account for a significant portion of the global energy demand. Nevertheless, the opportunity for RES integration in the energy supply of large food storage facilities is often neglected. In situ power generation using RES permits capture of a large portion of virtually free energy, thereby reducing dramatically the running costs and carbon footprint, while enhancing the economic competitiveness. In that context, there exist promising engineering solutions to exploit various renewables in the food preservation sector, in combination with the emerging sustainability-enhancing technology of Cryogenic Energy Storage (CES). Key findings and conclusions Substantial research endeavours are driven by the noble objective to turn the Europe's Energy Union into the world's number one in renewable energies. Integrating RES, in synchrony with CES development and proper control, is capable of both strengthening the food refrigeration sector and improving dramatically the power grid balance and energy system sustainability. Hence, this article aims to familiarise stakeholders of the European and global food preservation industry with state-of-the-art knowledge, know-how, opportunities and professional achievements in the concerned field
GlobSnow - a new contribution to global snow monitoring services
The GlobSnow project will be a complement within a
series of global pilot projects, developed with in the
ESA Data User Element, monitoring several Essential
Climate Variables (ECV) needed to support the climate
change monitoring requirements of the UNFCCC. In
particular the GlobSnow project will help to define,
develop and demonstrate a global snow monitoring
service based on satellite Earth Observation data
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