Oral Presentation
Poster Presentation
No. | Presentation Title | Author |
---|---|---|
Topic 1. Ongoing and Near-term Satellite Missions and Calibration | ||
1 | Spectral-radiance Inter-comparsion between GOSAT/FTS, GOSAT-2/FTS-2, and OCO-2 | F. Kataoka, RESTEC, Japan |
2 | Atmospheric Variations in Column Integrated CO2 On Synoptic and Seasonal Time Scales over the U.S. | Q. Wang, Univ. Oklahoma, US |
3 | Sensitivity Evaluation of TANSO-FTS/GOSAT Using Principal Component Analysis | Y. Someya, NIES, Japan |
4 | GOSAT-2 Cal/Val Phase Operation Plan for Ensuring the Consistency with GOSAT | K. Shiomi, JAXA, Japan |
5 | The Ability of GeoCarb to Constrain the Interannual Variability of Carbon Gases over the Amazon | B. Weir, USRA, US |
6 | Progress in Atmospheric Carbon Monitoring Using NASA's Goddard Earth Observing System (GEOS) Model and Data from the OCO and GOSAT Missions | B. Weir, USRA, US |
7 | The OCO-3 Mission: Global Observations of CO2 and Solar-Induced Fluorescence from the International Space Station - Snapshot Area Map and Target Mode Observations | T. Kurosu, JPL, US |
Topic 2. Retrieval Algorithms and Uncertainty Quantification | ||
8 | Exploring Improvements to the Aerosol Parameterization in the OCO-2 XCO2 Retrieval Algorithm | R. R. Nelson, JPL, US |
9 | Validation of Cloud Judgements in TANSO-FTS FOVs by Using Himawari-8/AHI Data | K. Kitamura, Chiba Univ., Japan |
10 | Carbon Dioxide Enhancement over Seoul from Space and Surface Measurements | C. Park, Seoul National Univ., Korea |
11 | Regeneration of CO2 Satellite Column Data Tailored to an Atmospheric Inversion Scheme | A. Webb, Univ. Leicester, UK |
14 | Characterization of OCO-2 and ACOS-GOSAT Biases and Errors for Flux Estimates | S. Kulawik, BAER Inst., US |
15 | Observing Patterns of Greenhouse Gases and Pollutants Across Cities Using Satellite Data | H. Park, Seoul National Univ., Korea |
16 | Preliminary Results from the ESA CH4TIR Project: Spectroscopy and Forward Model Error Improvement for CH4 Retrieval in the TIR | C. E. Robert, IASB-BIRA, Belgium |
17 | GOSAT-2/TANSO-CAI-2 and the Aerosol Product | M. Hashimoto, JAXA, Japan |
18 | Assessing OCO-2 Northern High Latitude XCO2 Retrievals Over Snow | J. Mendonca, ECCC, Canada |
19 | A Journey of the OCO-2 XCO2 Data Set from Version 9 to Version 10: the ACOS Retrieval Algorithm Validation | L. Kuai, JPL, US |
20 | TanSat XCO2 Retrieval, Inter-comparison and Validation | D. Yang, Univ. Leicester, UK |
21 | Observing Water Vapour in the Planetary Boundary Layer from the Short-Wave Infrared | T. Trent, Univ. Leicester, UK |
22 | Improvement and Application of PPDF-S Method for Retrieving XCO2 over Aerosol Dense Areas | C. Iwasaki, Univ. Tokyo, Japan |
28 | Variation of Carbon Dioxide at Upper Troposphere / Lower Stratosphere Derived from GOSAT TANSO-FTS TIR | A. Honda, Kyushu Univ., Japan |
29 | Validating Ratio Component XCH4/XCO2 of GOSAT Proxy Retrieval of Methane | H. Oshio, NIES, Japan |
57 | Simulation-retrieval Experiments over the Western Hemisphere with the GeoCarb Greenhouse Gas Retrieval Algorithm | G. McGarragh, Colorado State Univ., US |
Topic 3. Validation and Supporting Observations | ||
23 | Variations in CO2 and CH4 in Upper Atmosphere: the Effects of Biomass Burning and Asian Monsoon Transport Inferred from GOSAT/TANSO-FTS TIR Data | N. Saitoh, Chiba Univ., Japan |
24 | Greenhouse Gas Measurements at the Sodankyla; TCCON Site and Comparisons with the Satellite Borne Observations | R. Kivi, FMI, Finland |
25 | Profiles of Greenhouse Gases Measured in the 2018 STEAM Field Campaign | Z. Cai, CAS, China |
26 | Seasonal and Diurnal Opportunities for XCH4, XCO2, and XCO for the Amazonian Rainforest Region Allowing Sampling and Validation | R. Chatfield, NASA, US |
27 | Progress on Validation of the GOSAT and GOSAT-2 FTS SWIR L2 Products | I. Morino, NIES, Japan |
Topic 4. Flux Inversions from Space-based Greenhouse Gas Measurements | ||
30 | Comparison between MOPITT and OCO-2 Flux Inversions: Analyze of CO-CO2 Correlation | H. Peiro, Univ. Oklahoma, US |
31 | What Biogeochemical Processes Drive the Large Decrease of Atmospheric CO2 Growth Rate in 2017? | J. Liu, JPL, US |
32 | Characteristics of Atmospheric Carbon Dioxide Concentrations Based on GOSAT and Its Relations to Biomass Burning in China | Y. Shi, CAS, China |
33 | Mesoscale Atmospheric Inversion of the CO2 Natural Fluxes in Amazonia Using GeoCarb and MicroCarb Data | S. K. Singh, LSCE, France |
34 | Assessing Errors and Uncertainties in a Global, High-resolution, Fossil-fuel CO2 Emission Dataset | T. Oda, NASA, US |
35 | Solving Methane Fluxes at Northern Latitudes using Atmospheric and Soil Earth Observations Data | H. Lindqvist, FMI, Finland |
36 | Relationship between Methane Enhancements Observed by GOSAT and Country Scale Anthropogenic Emissions in Asia | R. Janardanan, NIES, Japan |
37 | Characterizing and Mitigating the Impact of Model Transport Errors on CO2 Flux Estimates in the Assimilation of XCO2 Data from OCO-2 | D. Jones, Univ. Toronto, Canada |
38 | The Seasonal and Inter-annual Variations of Regional CO2 and CH4 Fluxes Estimated from GOSAT Data | H. Takagi, NIES, Japan |
39 | Comparing National Methane Emissions Inventories with Estimates by the Global High-resolution Inverse Model | F. Wang, NIES, Japan |
40 | lnverse Modeling of Anthropogenic Methane Emissions Based on Ground-based Monitoring and GOSAT Satellite Retrievals | A. Tsuruta, FMI, Finland |
Topic 5. Solar-Induced Chlorophyll Fluorescence (SIF) | ||
41 | Retrieval of Solar-induced Chlorophyll Fluorescence from TanSat Space Measurements | L. Yao, CAS, China |
42 | Long-term Evaluation of Zero-level Offset in GOSAT FTS O2 A-band and Consistency of the Derived SIF with OCO-2 SIF | H. Oshio, NIES, Japan |
43 | Assessing the Temporal Dynamics of Satellite-derived Photochemical Reflectance Index (PRI) and Solar-induced Fluorescence (SIF) in Climate-changing Mongolia | T. Kiyono, NIES, Japan |
44 | Solar induced Fluorescence (SIF) Mapping from the Copernicus Anthropogenic CO2 Monitoring Mission | H. Boesch, Univ. Leicester, UK |
45 | Implementing SIF Estimation Process to the Terrestrial Ecosystem Model VISIT and Applying the Radiation Transfer Model | T. Miyauchi, NIES, Japan |
Topic 6. Related Ground-based, Ship-borne, and Air-borne Measurements | ||
46 | Methane Isotopologue Parameter Assessment of Multiple Spectral Databases Using TCCON | E. Malina, ESA |
47 | In situ Measurement of Vertical Distribution of CO2 and CH4 in the Troposphere by Aircraft and Tethered Balloon | X. Sun, CAS, China |
48 | Measuring In-situ CO2 Profile and Comparison with Satellites and Model | Y. Yi, CAS, China |
49 | Provision of GOSAT Data from the WDCGG Website | A. Kinoshita, JMA, Japan |
50 | Intercomparison of XCO2, XCH4, XCO Measurements Using EM27/SUN and IFS125HR in Xianghe | K. Che, CAS, China |
51 | Towards Tracking East Asian Transport of Pollution Using the Burgos TCCON Site and the GOSAT Series Satellites | V. A. Velazco, Univ. Wollongong, Australia |
52 | Intercomparison between TCCON XCO2 and XCH4 data in Japan and Philippines via a Portable Fourier Transform Spectrometer | H. Ohyama, NIES, Japan |
53 | Ground-based Measurement of Solar-induced Chlorophyll Fluorescence with High-resolution Spectrum in Paddy Field Ecosystem, Japan | K. Buareal, Hokkaido Univ., Japan |
54 | Quick Look Algorithm for GHG Source Detection by Using Airborne Imaging Spectrometer Suite | T. Kawashima, RESTEC, Japan |
Topic 7. Status of Future Satellite Missions about GHG Monitoring | ||
55 | A Multi-wavelength Integrated Path Differential Absorption Lidar to Measure XCO2 from Space: Status | J. B. Abshire, NASA, US |
56 | NASA's Carbon Cycle OSSE Initiative - Informing Future Space-based Observing Strategies through Advanced Modeling and Data Assimilation | L. Ott, NASA, US |
IWGGMS-15 Secretariat
Telephone: +(81) 29-850-2550/2966
Fax: +(81) 29-850-2219
E-mail: iwggms-15[at]nies.go.jp