| Preface | p. v |
| p. vii |
| List of Contributors | p. xiii |
| TROPOSAT: the project and the scientific highlights | p. 1 |
| Introduction | p. 1 |
| The aims of TROPOSAT | p. 2 |
| Some TROPOSAT scientific highlights and activities | p. 2 |
| Policy-relevant results | p. 7 |
| Future perspectives and opportunities | p. 9 |
| TROPOSAT organisational activities | p. 11 |
| Further information | p. 12 |
| An Overview of the Scientific Activities and Achievements | p. 13 |
| New algorithms for obtaining tropospheric data from satellite measurements | p. 13 |
| Applications of satellite data in tropospheric research | p. 29 |
| Synergistic use of different instrumentation and platforms for tropospheric measurements | p. 35 |
| Validation and data assimilation for tropospheric satellite data products | p. 43 |
| The use of data assimilation to augment the utility of satellite data | p. 47 |
| Future space infrastructure | p. 51 |
| Tropospheric Data from the United States | p. 55 |
| Development of Algorithms | p. 59 |
| Retrieval of Greenhouse and Related Gas Parameters from SCIAMACHY/ENVISAT | p. 59 |
| Aerosol Retrieval by the Introduction of New Aerosol Classes and Optical Properties: Methods and Climatology | p. 65 |
| Neural Network Ozone Profile Retrieval System for GOME Spectra (NNORSY-GOME) | p. 77 |
| Retrieval and Data Assimilation Algorithm Development for Tropospheric Ozone and NO2 from GOME and SCIAMACHY | p. 87 |
| Retrieval of Tropospheric Aerosol Properties from Space using MISR Data | p. 97 |
| The Role of Polarisation Measurements in Ozone Profile Retrieval from Back-scattered Ultraviolet Sunlight | p. 107 |
| Retrieval of Aerosol Properties from Satellite Data | p. 117 |
| Retrieval of CO Column and Profile Data from the MOPITT Instrument on EOS-TERRA | p. 125 |
| Quantification of Tropospheric Measurements from Nadir Viewing UV/Visible Instruments | p. 137 |
| Retrieval of Upper Tropospheric H2O from CRISTA-2 Observations | p. 149 |
| Retrieval of Tropospheric BrO and NO2 from UV-Visible Observations | p. 155 |
| Retrievability of Upper Tropospheric Species and Parameters from MIPAS/ENVISAT Data | p. 167 |
| Assessment of the Global Distribution of Tropospheric OH Radical Production from GOME Observations | p. 181 |
| A Ground Validation Station for the Satellite-based Atmospheric Sensor Instruments GOME and SCIAMACHY | p. 187 |
| Development of Satellite-derived Information on Tropospheric Actinic Flux and Aerosol Particulate Matter | p. 189 |
| Case Studies for the Investigation of Cloud Sensitive Parameters as Measured by GOME | p. 199 |
| Ozone Profile Retrieval from Broadband Nadir UV/Visible Satellite Spectra: How Accurate is the Tropospheric Profile? | p. 211 |
| Use of Satellite Data to understand Atmospheric Processes | p. 227 |
| Tropospheric Aerosol Modelling | p. 227 |
| Validation of a Fully Coupled Chemistry-Climate Model | p. 231 |
| Global Photochemical Model Evaluation using GOME Tropospheric Column Data | p. 241 |
| Construction and Analysis of Image Sequences of Atmospheric Trace Gases | p. 251 |
| Use of GOME Measurements for the Examination of the Nitrogen Oxide Budget in the Troposphere | p. 255 |
| Use of Satellite Data to Constrain Ozone Budgets in Global Tropospheric Chemistry Models | p. 259 |
| First Validation of Tropospheric NO2 Column Densities Retrieved from GOME by in situ Aircraft Profile Measurements | p. 265 |
| Determination of NOx Sources by Combination of Satellite Images with Transport Modelling | p. 271 |
| The Use of Space-borne Measurements and the Ground-based Swiss Monitoring System for Tracing Atmospheric Pollution | p. 281 |
| Synergistic Use of Different Instrumentation and Platforms for Tropospheric Measurements | p. 291 |
| Comparing CARIBIC and Satellite Data | p. 291 |
| Studies of NO2 from Lightning and Convective Uplifting using GOME Data | p. 297 |
| Scientific Applications of Satellite Data within the Geophysica Research Community | p. 307 |
| Retrieval of Tropospheric Information from Ground-based FTIR Observations, Supported by Synergistic Exploitation of Various Ground-based and Space-borne Measurement Techniques and Data | p. 315 |
| The Development of Multi-platform Methods for Derivation of Tropospheric Composition from Space | p. 327 |
| Control Mechanisms of Water Vapour in the Upper Troposphere: Large Scale Subsidence in Regions of Tropical Cb-Convection | p. 337 |
| Satellite plus Ground-based FTIR Measurements for Tropospheric Studies: Towards an Integrated Global Measurement System (IGMS) and an Improved Validation Strategy | p. 345 |
| Methodology for Using the MOZAIC Ozone Climatology in Future Comparisons with Data from SCIAMACHY Onboard ENVISAT | p. 355 |
| Validation and Data Assimilation for Tropospheric Satellite Data Products | p. 361 |
| Validation of CO and CH4 Retrieved from SCIAMACHY | p. 361 |
| Database Support for Use and Usability of Satellite Data | p. 373 |
| Emission Rate Estimates by Variational Assimilation of Surface and Satellite Data | p. 375 |
| Satellite Validation using Ground-based Spectroscopic Techniques | p. 381 |
| Airborne in-situ Measurements of Radiation, Aerosol Optical Properties and Trace Gases for Evaluation of Remote SensingTechniques | p. 391 |
| Co-ordination of the Validation Activities for SCIAMACHY | p. 397 |
| A New Airborne DIAL System for Tropospheric Ozone Measurements | p. 401 |
| Monitoring of the Variability and Long-term Evolution of Tropospheric Constituents by Infrared Solar Absorption Spectrometry at the Jungfraujoch, Switzerland | p. 407 |
| Tropospheric satellite data available | p. 417 |
| Publications and Theses resulting from TROPOSAT work | p. 421 |
| Organisation of TROPOSAT | p. 435 |
| Index | p. 439 |
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