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2. Development and assessment of the SMAP enhanced passive soil moisture product

Author

Chan, S.K., Bindlish, R., O'Neill, P., Jackson, T., Njoku, E., Dunbar, S., Chaubell, J., Piepmeier, J., Yueh, S., Entekhabi, D., Colliander, A., Chen, F., Cosh, M.H., Caldwell, T., Walker, J., Berg, A., McNairn, H., Thibeault, M., Martínez-Fernández, J., Uldall, F., Seyfried, M., Bosch, D., Starks, P., Holifield Collins, C., Prueger, J., van der Velde, R., Asanuma, J., Palecki, M., Small, E.E., Zreda, M., Calvet, J., Crow, W.T., and Kerr, Y.

Published
2018
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3. Validation of SMAP surface soil moisture products with core validation sites

Author

Colliander, A., Jackson, T.J., Bindlish, R., Chan, S., Das, N., Kim, S.B., Cosh, M.H., Dunbar, R.S., Dang, L., Pashaian, L., Asanuma, J., Aida, K., Berg, A., Rowlandson, T., Bosch, D., Caldwell, T., Caylor, K., Goodrich, D., al Jassar, H., Lopez-Baeza, E., Martínez-Fernández, J., González-Zamora, A., Livingston, S., McNairn, H., Pacheco, A., Moghaddam, M., Montzka, C., Notarnicola, C., Niedrist, G., Pellarin, T., Prueger, J., Pulliainen, J., Rautiainen, K., Ramos, J., Seyfried, M., Starks, P., Su, Z., Zeng, Y., van der Velde, R., Thibeault, M., Dorigo, W., Vreugdenhil, M., Walker, J.P., Wu, X., Monerris, A., O'Neill, P.E., Entekhabi, D., Njoku, E.G., and Yueh, S.

Published
2017
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4. Performance of SMOS Soil Moisture Products over Core Validation Sites

Author

Colliander, A., primary, Kerr, Y., additional, Wigneron, J-P., additional, Al-Yaari, A., additional, Rodriguez-Fernandez, N., additional, Li, X., additional, Chaubell, J., additional, Richaume, P., additional, Mialon, A., additional, Asanuma, J., additional, Berg, A., additional, Bosch, D.D., additional, Caldwell, T., additional, Cosh, M.H., additional, Holifield Collins, C., additional, Martínez-Fernández, J., additional, McNairn, H., additional, Seyfried, M.S., additional, Starks, P.J., additional, Su, Z., additional, Thibeault, M., additional, and Walker, J.P., additional

Published
2023
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5. Seasonal Dependence of SMAP Radiometer-Based Soil Moisture Performance as Observed over Core Validation Sites

Author

Colliander, A, Jackson, T. J, Chan, S. K, O'Neill, P, Bindlish, R, Cosh, M. H, Caldwell, T, Walker, J. P, Berg, A, McNairn, H, Thibeault, M, Martinez-Fernandez, J, Jensen, K. H, Asanuma, J, Seyfried, M. S, Bosch, D. D, Starks, P. J, Holifield Collins, C, Prueger, J. H, Su, Z, and Yueh, S. H

Subjects
Earth Resources And Remote Sensing, Geophysics
Abstract

The NASA SMAP (Soil Moisture Active Passive) mission provides a global coverage of soil moisture measurements based on its L-band microwave radiometer every 2-3 days at about 40 km resolution. The soil moisture retrieval algorithms model the brightness temperature as a function of soil moisture, surface conditions and vegetation. External data sources inform the algorithms about the surface conditions and vegetation, which enable the retrieval of soil moisture. The inversion process contains uncertainties related to radiometer measurements, forward model assumptions and ancillary data sources. This study focuses on the uncertainties that depend on the seasonal evolution of the surface conditions and vegetation. This study compares the SMAP and core validation site (CVS) soil moisture values over a period of three years to extract the evolution of performance metrics over time. The analysis showed that most CVS that include managed agriculture exhibit significant time-dependent seasonal bias. This bias was linked to seasonal temperature cycle, which is a proxy to several features that can cause seasonally dependent errors in the SMAP product.

Published
2019

7. An Assessment of the Differences Between Spatial Resolution and Grid Size for the SMAP Enhanced Soil Moisture Product over Homogeneous Sites

Author

Colliander, A, Jackson, T. J, Chan, S. K, O'neill, P, Bindlish, R, Cosh, M. H, Caldwell, D, Walker, J. P, Berg, A, McNairn, H, Thibeault, M, Martinez-Fernandez, J, Jensen, K. H, Asanuma, J, Seyfried, M. S, Bosch, D. D, Starks, P. J, Holifield Collins, C, Prueger, J. H, Su, Z, Lopez-Baeza, E, and Yueh, S. H

Subjects
Earth Resources And Remote Sensing
Abstract

Satellite-based passive microwave remote sensing typically involves a scanning antenna that makes measurements at irregularly spaced locations. These locations can change on a day to day basis. Soil moisture products derived from satellite-based passive microwave remote sensing are usually resampled to a fixed Earth grid that facilitates their use in applications. In many cases the grid size is finer than the actual spatial resolution of the observation, and often this difference is not well understood by the user. Here, this issue was examined for the Soil Moisture Active Passive (SMAP) enhanced version of the passive-based soil moisture product, which has a grid size of 9-km and a nominal spatial resolution of 33-km. In situ observations from core validation sites were used to compute comparison metrics. For sites that satisfied the established reliability and scaling criteria, the impact of validating the 9-km grid product with in situ data collected over a 9-km versus a 33-km domain was very small for the sites studied (0.039 cu. m/cu. m unbiased root mean square difference for the 9-km case versus 0.037 cu. m/cu. m for the 33-km case). This result does not mean that the resolution of the product is 9-km but that for the conditions studied here the soil moisture estimated from in situ observations over 9-km is a close approximation of the soil moisture estimated from in situ observations over the 33-km resolution. The implication is that using the enhanced SMAP product at its grid resolution of 9-km should not introduce large errors in most applications.

Published
2018
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8. AMSR2 Soil Moisture Product Validation

Author

Bindlish, R, Jackson, T, Cosh, M, Koike, T, Fuiji, X, de Jeu, R, Chan, S, Asanuma, J, Berg, A, Bosch, D, Caldwell, T, Collins, C. Holyfield, McNairn, H, Martinez-Fernandez, J, Prueger, J, Seyfried, M, Starks, P, Su, Z, Thibeault, M, and Walker, J

Subjects
Earth Resources And Remote Sensing
Abstract

The Advanced Microwave Scanning Radiometer 2 (AMSR2) is part of the Global Change Observation Mission-Water (GCOM-W) mission. AMSR2 fills the void left by the loss of the Advanced Microwave Scanning Radiometer Earth Observing System (AMSR-E) after almost 10 years. Both missions provide brightness temperature observations that are used to retrieve soil moisture. Merging AMSR-E and AMSR2 will help build a consistent long-term dataset. Before tackling the integration of AMSR-E and AMSR2 it is necessary to conduct a thorough validation and assessment of the AMSR2 soil moisture products. This study focuses on validation of the AMSR2 soil moisture products by comparison with in situ reference data from a set of core validation sites. Three products that rely on different algorithms were evaluated; the JAXA Soil Moisture Algorithm (JAXA), the Land Parameter Retrieval Model (LPRM), and the Single Channel Algorithm (SCA). Results indicate that overall the SCA has the best performance based upon the metrics considered.

Published
2017

9. Assessment of Version 4 of the SMAP Passive Soil Moisture Standard Product

Author

O'neill, P. O, Chan, S, Bindlish, R, Jackson, T, Colliander, A, Dunbar, R, Chen, F, Piepmeier, Jeffrey R, Yueh, S, Entekhabi, D, Cosh, M, Caldwell, T, Walker, J, Wu, X, Berg, A, Rowlandson, T, Pacheco, A, McNairn, H, Thibeault, M, Martínez-Fernández, J, González-Zamora, A, Lopez-Baeza, E, Udall, F, Seyfried, M, Bosch, D, Starks, P, Holifield, C, Prueger, J, Su, Z, Van der Velde, R, Asanuma, J, Palecki, M, Small, E, Zreda, M, Calvet, J-C, Crow, W, and Kerr, Y

Subjects
Earth Resources And Remote Sensing
Abstract

NASAs Soil Moisture Active Passive (SMAP) mission launched on January 31, 2015 into a sun-synchronous 6 am6 pm orbit with an objective to produce global mapping of high-resolution soil moisture and freeze-thaw state every 2-3 days. The SMAP radiometer began acquiring routine science data on March 31, 2015 and continues to operate nominally. SMAPs radiometer-derived standard soil moisture product (L2SMP) provides soil moisture estimates posted on a 36-km fixed Earth grid using brightness temperature observations and ancillary data. A beta quality version of L2SMP was released to the public in October, 2015, Version 3 validated L2SMP soil moisture data were released in May, 2016, and Version 4 L2SMP data were released in December, 2016. Version 4 data are processed using the same soil moisture retrieval algorithms as previous versions, but now include retrieved soil moisture from both the 6 am descending orbits and the 6 pm ascending orbits. Validation of 19 months of the standard L2SMP product was done for both AM and PM retrievals using in situ measurements from global core calval sites. Accuracy of the soil moisture retrievals averaged over the core sites showed that SMAP accuracy requirements are being met.

Published
2017

10. Development and Validation of The SMAP Enhanced Passive Soil Moisture Product

Author

Chan, S, Bindlish, R, O'Neill, P, Jackson, T, Chaubell, J, Piepmeier, J, Dunbar, S, Colliander, A, Chen, F, Entekhabi, D, Yeuh, S, Cosh, M, Caldwell, T, Walker, J, Wu, X, Berg, A, Rowlandson, T, Pacheco, A, McNairn, H, Thibeault, M, Martínez-Fernández, J, González-Zamora, A, Lopez-Baeza, E, Uldall, F, Seyfried, M, Bosch, D, Starks, P, Holifield, C, Prueger, J, Su, Z, van der Velde, R, Asanuma, J, Palecki, M, Small, E, Zreda, M, Calvet, J-C, Crow, W, and Kerr, Y

Subjects
Earth Resources And Remote Sensing
Abstract

Since the beginning of its routine science operation in March 2015, the NASA SMAP observatory has been returning interference-mitigated brightness temperature observations at L-band (1.41 GHz) frequency from space. The resulting data enable frequent global mapping of soil moisture with a retrieval uncertainty below 0.040 cu m/cu m at a 36 km spatial scale. This paper describes the development and validation of an enhanced version of the current standard soil moisture product. Compared with the standard product that is posted on a 36 km grid, the new enhanced product is posted on a 9 km grid. Derived from the same time-ordered brightness temperature observations that feed the current standard passive soil moisture product, the enhanced passive soil moisture product leverages on the Backus-Gilbert optimal interpolation technique that more fully utilizes the additional information from the original radiometer observations to achieve global mapping of soil moisture with enhanced clarity. The resulting enhanced soil moisture product was assessed using long-term in situ soil moisture observations from core validation sites located in diverse biomes and was found to exhibit an average retrieval uncertainty below 0.040 cu m/cu m. As of December 2016, the enhanced soil moisture product has been made available to the public from the NASA Distributed Active Archive Center at the National Snow and Ice Data Center.

Published
2017

12. Seasonal Dependence of SMAP Radiometer-Based Soil Moisture Performance as Observed over Core Validation Sites

Author

Colliander, A., Jackson, T. J., Chan, S. K., O'Neill, P., Bindlish, R., Cosh, M. H., Caldwell, T., Walker, J. P., Berg, A., McNairn, H., Thibeault, M., Martinez-Fernandez, J., Jensen, K. H., Asanuma, J., Seyfried, M. S., Bosch, D. D., Starks, P. J., Holifield Collins, C., Prueger, J. H., Su, Z., Yueh, S. H., Colliander, A., Jackson, T. J., Chan, S. K., O'Neill, P., Bindlish, R., Cosh, M. H., Caldwell, T., Walker, J. P., Berg, A., McNairn, H., Thibeault, M., Martinez-Fernandez, J., Jensen, K. H., Asanuma, J., Seyfried, M. S., Bosch, D. D., Starks, P. J., Holifield Collins, C., Prueger, J. H., Su, Z., and Yueh, S. H.

Abstract

The NASA SMAP (Soil Moisture Active Passive) mission provides a global coverage of soil moisture measurements based on its L-band microwave radiometer every 2-3 days at about 40 km resolution. The soil moisture retrieval algorithms model the brightness temperature as a function of soil moisture, surface conditions and vegetation. External data sources inform the algorithms about the surface conditions and vegetation, which enable the retrieval of soil moisture. The inversion process contains uncertainties related to radiometer measurements, forward model assumptions and ancillary data sources. This study focuses on the uncertainties that depend on the seasonal evolution of the surface conditions and vegetation. The study compares the SMAP and core validation site (CVS) soil moisture values over a period of four years to extract the evolution of performance metrics over time. The analysis showed that most CVS that include managed agriculture exhibit significant time-dependent seasonal bias. This bias was linked to seasonal temperature cycle, which is a proxy to several features that can cause seasonally dependent errors in the SMAP product.

Published
2019

13. Seasonal Dependence of SMAP Radiometer-Based Soil Moisture Performance as Observed Over Core Validation Sites

Author

Colliander, A., primary, McNairn, H., additional, Thibeault, M., additional, Martinez-Fernandez, J., additional, Jensen, K.H., additional, Asanuma, J., additional, Seyfried, M.S., additional, Bosch, D.D., additional, Starks, P.J., additional, Holifield Collins, C., additional, Prueger, J.H., additional, Jackson, T.J., additional, Su, Z., additional, Yueh, S. H., additional, Chan, S.K., additional, O'Neill, P., additional, Bindlish, R., additional, Cosh, M. H., additional, Caldwell, T., additional, Walker, J. P., additional, and Berg, A., additional

Published
2019
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14. An assessment of the differences between spatial resolution and grid size for the SMAP enhanced soil moisture product over homogeneous sites

Author

Colliander, A., Jackson, T. J., Chan, S. K., O'Neill, P., Bindlish, R., Cosh, M. H., Caldwell, T., Walker, J. P., Berg, A., McNairn, H., Thibeault, M., Martínez-Fernández, J., Jensen, K. H., Asanuma, J., Seyfried, M. S., Bosch, D. D., Starks, P. J., Holifield Collins, C., Prueger, J. H., Su, Z., Lopez-Baeza, E., Yueh, S. H., Colliander, A., Jackson, T. J., Chan, S. K., O'Neill, P., Bindlish, R., Cosh, M. H., Caldwell, T., Walker, J. P., Berg, A., McNairn, H., Thibeault, M., Martínez-Fernández, J., Jensen, K. H., Asanuma, J., Seyfried, M. S., Bosch, D. D., Starks, P. J., Holifield Collins, C., Prueger, J. H., Su, Z., Lopez-Baeza, E., and Yueh, S. H.

Abstract

Satellite-based passive microwave remote sensing typically involves a scanning antenna that makes measurements at irregularly spaced locations. These locations can change on a day to day basis. Soil moisture products derived from satellite-based passive microwave remote sensing are usually resampled to a fixed Earth grid that facilitates their use in applications. In many cases the grid size is finer than the actual spatial resolution of the observation, and often this difference is not well understood by the user. Here, this issue was examined for the Soil Moisture Active Passive (SMAP) enhanced version of the passive-based soil moisture product, which has a grid size of 9-km and a nominal spatial resolution of 33-km. In situ observations from core validation sites were used to compute comparison metrics. For sites that satisfied the established reliability and scaling criteria, the impact of validating the 9-km grid product with in situ data collected over a 9-km versus a 33-km domain was very small for the sites studied (0.039 m3/m3 unbiased root mean square difference for the 9-km case versus 0.037 m3/m3 for the 33-km case). This result does not mean that the resolution of the product is 9-km but that for the conditions studied here the soil moisture estimated from in situ observations over 9-km is a close approximation of the soil moisture estimated from in situ observations over the 33-km resolution. The implication is that using the enhanced SMAP product at its grid resolution of 9-km should not introduce large errors in most applications.

Published
2018

15. Assessment of Version 4 of the SMAP Passive Soil Moisture

Author

Neill, Peggy O., Chan, S., Bindlish, R., Jackson, T., Chaubell, J., Piepmeijer, J., Dunbar, A., Cosh, M., Colliander, A., Chen, F., Entekhabi, D., Yeuh, S., Caldwell, T., Jeffrey Walker, Wu, X., Berg, A., Rowlandson, T., Pacheco, T., Mcnairn, H., Thibeault, M., Martinez-Fernandez, J., Gonzalez-Zamora, A., Lopez-Beaza, E., Uldall, F., Seyfried, M., David Bosch, Starks, P. J., Holifield Collins, Chandra D., Prueger, J. H., Zhongbo Su, Rogier van der Velde, Asanuma, J., Palecki, E., Small, E., Zreda, M., Calvet, J. C., Crow, C., Kerr, Y. H., and Department of Water Resources

Published
2017

16. Development and Validation of The SMAP Enhanced Passive Soil Moisture Product : open access

Author

Chan, S., Bindlish, R., Neill, P. E. O., Jackson, T., Chaubell, J., Piepmeijer, J., Dunbar, A., Cosh, M., Colliander, F., Chen, F., Entekhabi, D., Yeuh, S., Caldwell, T., Jeffrey Walker, Wu, X., Berg, A., Rowlandson, T., Pacheco, P., Mcnairn, H., Thibeault, M., Martinez-Fernandez, J., Gonzalez-Zamora, A., Lopez-Beaza, E., Uldall, F., Seyfried, M., David Bosch, Patrick Starks, Holifield Collins, Chandra D., Prueger, J., Zhongbo Su, Rogier van der Velde, Asanuma, J., Palecki, E., Small, E., Zreda, M., Calvet, J. C., Crow, C., Kerr, Y. H., and Department of Water Resources

Published
2017

17. Development and validation of the SMAP enhanced passive soil moisture product

Author

Chan, S., primary, Bindlish, R., additional, O'Neill, P., additional, Jackson, T., additional, Chaubell, J., additional, Piepmeier, J., additional, Dunbar, S., additional, Colliander, A., additional, Chen, F., additional, Entekhabi, D., additional, Yueh, S., additional, Cosh, M., additional, Caldwell, T., additional, Walker, J., additional, Wu, X., additional, Berg, A., additional, Rowlandson, T., additional, Pacheco, A., additional, McNairn, H., additional, Thibeault, M., additional, Martinez-Fernandez, J., additional, Gonzalez-Zamora, A., additional, Lopez-Baeza, E., additional, Uldall, F., additional, Seyfried, M., additional, Bosch, D., additional, Starks, P., additional, Collins, C. Holifield, additional, Prueger, J., additional, Su, Z., additional, van der Velde, R., additional, Asanuma, J., additional, Palecki, M., additional, Small, E., additional, Zreda, M., additional, Calvet, J-C., additional, Crow, W., additional, and Kerr, Y., additional

Published
2017
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18. AMSR2 soil moisture product validation

Author

Bindlish, R., primary, Jackson, T., additional, Cosh, M., additional, Koike, T., additional, Fuiji, X., additional, de Jeu, R., additional, Chan, S., additional, Asanuma, J., additional, Berg, A., additional, Bosch, D., additional, Caldwell, T., additional, Collins, C. Holyfield, additional, McNairn, H., additional, Martinez-Fernandez, J., additional, Prueger, J., additional, Seyfried, M., additional, Starks, P., additional, Su, Z., additional, Thibeault, M., additional, and Walker, J., additional

Published
2017
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19. Assessment of version 4 of the SMAP passive soil moisture standard product

Author

O'Neill, P., primary, Chan, S., additional, Bindlish, R., additional, Jackson, T., additional, Colliander, A., additional, Dunbar, S., additional, Chen, F., additional, Piepmeier, J., additional, Yueh, S., additional, Entekhabi, D., additional, Cosh, M., additional, Caldwell, T., additional, Walker, J., additional, Wu, X., additional, Berg, A., additional, Rowlandson, T., additional, Pacheco, A., additional, McNairn, H., additional, Thibeault, M., additional, Martinez-Fernandez, J., additional, Gonzalez-Zamora, A., additional, Lopez-Baeza, E., additional, Udall, F., additional, Seyfried, M., additional, Bosch, D., additional, Starks, P., additional, Holifield, C., additional, Prueger, J., additional, Su, Z., additional, van der Velde, R., additional, Asanuma, J., additional, Palecki, M., additional, Small, E., additional, Zreda, M., additional, Calvet, J-C., additional, Crow, W., additional, and Kerr, Y., additional

Published
2017
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20. NDVI responses to the forest canopy and floor from spring to summer observed by airborne spectrometer in eastern Siberia

Author

Suzuki, R., Kobayashi, H., Delbart, Nicolas, Asanuma, J., Hiyama, T., Centre d'études spatiales de la biosphère (CESBIO), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS), Pôle de recherche pour l'organisation et la diffusion de l'information géographique (PRODIG), Université Paris 1 Panthéon-Sorbonne (UP1)-Institut de Recherche pour le Développement (IRD)-École pratique des hautes études (EPHE), and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris-Sorbonne (UP4)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SHS.GEO]Humanities and Social Sciences/Geography, ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2011

21. Simulating carbon and water cycles of larch forests in East Asia by the BIOME-BGC model with AsiaFlux data

Author

Ueyama, M., Ichii, K., Hirata, R., Takagi, K., Asanuma, J., Machimura, T., Nakai, Y., Ohta, T., Saigusa, N., Takahashi, Y., Hirano, T., Ueyama, M., Ichii, K., Hirata, R., Takagi, K., Asanuma, J., Machimura, T., Nakai, Y., Ohta, T., Saigusa, N., Takahashi, Y., and Hirano, T.

Abstract

Larch forests are widely distributed across many cool-temperate and boreal regions, and they are expected to play an important role in global carbon and water cycles. Model parameterizations for larch forests still contain large uncertainties owing to a lack of validation. In this study, a process-based terrestrial biosphere model, BIOME-BGC, was tested for larch forests at six AsiaFlux sites and used to identify important environmental factors that affect the carbon and water cycles at both temporal and spatial scales. The model simulation performed with the default deciduous conifer parameters produced results that had large differences from the observed net ecosystem exchange (NEE), gross primary productivity (GPP), ecosystem respiration (RE), and evapotranspiration (ET). Therefore, we adjusted several model parameters in order to reproduce the observed rates of carbon and water cycle processes. This model calibration, performed using the AsiaFlux data, substantially improved the model performance. The simulated annual GPP, RE, NEE, and ET from the calibrated model were highly consistent with observed values. The observed and simulated GPP and RE across the six sites were positively correlated with the annual mean air temperature and annual total precipitation. On the other hand, the simulated carbon budget was partly explained by the stand disturbance history in addition to the climate. The sensitivity study indicated that spring warming enhanced the carbon sink, whereas summer warming decreased it across the larch forests. The summer radiation was the most important factor that controlled the carbon fluxes in the temperate site, but the VPD and water conditions were the limiting factors in the boreal sites. One model parameter, the allocation ratio of carbon between belowground and aboveground, was site-specific, and it was negatively correlated with the annual climate of annual mean air temperature and total precipitation. Although this study substantially imp

Published
2010

29. Impact of meteorological anomalies in the 2003 summer on gross primary productivity in East Asia.

Author

Saigusa, N., Ichii, K., Murakami, H., Hirata, R., Asanuma, J., Den, H., Han, S.-J., Ide, R., Li, S.-G., Ohta, T., Sasai, T., S.-Q. Wang, and G.-R. Yu

Subjects
WEATHER, SUMMER, REMOTE sensing, FORESTS & forestry
Abstract

Northern Eurasia experienced anomalous weather conditions in the 2003 summer. We examined how forest ecosystems responded to the meteorological anomalies during the period using the dataset collected at flux monitoring sites in Asia, including a boreal forest in Mongolia, temperate forests in China and Japan, and a sub-tropical forest in China, as well as the dataset from satellite remote sensing. From July to August 2003, an active rain band stayed in the mid-latitude in East Asia for an unusually long period. Under the influence of the rain band, the gross primary production (GPP) of temperate forests was 20-30% lower in the 2003 summer than in other years due to significant reduction in the photosynthetic photon flux density (PPFD). The GPP of a cool-temperate forest in the north of the rain band was slightly enhanced by the higher PPFD; however, the GPP of a sub-tropical forest located in the south of the rain band was reduced by drought stress due to extremely hot and dry conditions. The correlation coefficients for the year-to-year changes in the PPFD and GPP during mid-summer were calculated, and the spatial distribution was examined. The spatial pattern of the PPFD was calculated by satellite data, and that of the GPP was estimated by a regression-type model, which was trained and tested by ground observation data. The correlation was positive in the mid- and high-latitudes since light was an essential factor of the summer GPP. On the other hand, a negative correlation appeared in the lower latitudes, suggesting that the water limitation was much more important than the PPFD in the region. Our study illustrated that the integration of flux data from wide areas by combining satellite remote sensing data can help us gain an understanding of the ecosystem responses to large-scale meteorological phenomena. [ABSTRACT FROM AUTHOR]

Published
2009
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30. Simulating carbon and water cycles of larch forests in East Asia by the BIOME-BGC model with AsiaFlux data.

Author

Ueyama, M., Ichii, K., Hirata, R., Takagi, K., Asanuma, J., Machimura, T., Nakai, Y., Ohta, T., Saigusa, N., Takahashi, Y., and Hirano, T.

Subjects
CARBON cycle, WATER bikes, FORESTS & forestry, EDDY flux, EVAPOTRANSPIRATION, METEOROLOGICAL precipitation
Abstract

Larch forests are widely distributed across many cool-temperate and boreal regions, and they are expected to play an important role in global carbon and water cycles. Model parameterizations for larch forests still contain large uncertainties owing to a lack of validation. In this study, a process-based terrestrial biosphere model, BIOMEBGC, was tested for larch forests at six AsiaFlux sites and used to identify important environmental factors that affect the carbon and water cycles at both temporal and spatial scales. The model simulation performed with the default deciduous conifer parameters produced results that had large differences from the observed net ecosystem exchange (NEE), gross primary productivity (GPP), ecosystem respiration (RE), and evapotranspiration (ET). Therefore, we adjusted several model parameters in order to reproduce the observed rates of carbon and water cycle processes. This model calibration, performed using the AsiaFlux data, significantly improved the model performance. The simulated annual GPP, RE, NEE, and ET from the calibrated model were highly consistent with observed values. The observed and simulated GPP and RE across the six sites are positively correlated with the annual mean air temperature and annual total precipitation. On the other hand, the simulated carbon budget is partly explained by the stand disturbance history in addition to the climate. The sensitivity study indicates that spring warming enhances the carbon sink, whereas summer warming decreases it across the larch forests. The summer radiation is the most important factor that controls the carbon fluxes in the temperate site, but the VPD and water conditions are the limiting factors in the boreal sites. One model parameter, the allocation ratio of carbon between aboveground and belowground, is site-specific, and it is negatively correlated with the annual climate of annual mean air temperature and total precipitation. Although this study significantly improves the model performance, the uncertainties that remain in terms of the sensitivity to water conditions should be examined in ongoing and long-term observations. [ABSTRACT FROM AUTHOR]

Published
2009
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31. Land surface identification near Yakutsk in eastern Siberia using video images taken from a hedgehopping aircraft.

Author

Suzuki, R., Hiyama**, T., Asanuma, J., and Ohata, T.

Subjects
REMOTE-sensing images, AERIAL photographs, SURVEYING (Engineering), RADAR in surveying, GEOGRAPHY
Abstract

Aircraft-based remote sensing was carried out over the Lena River region (approximately 100 km horizontal scale) near Yakutsk, in eastern Siberia, on nine days between 24 April and 19 June 2000. A home-use video camera was installed on the aircraft and aerial images of the land surface were recorded. By flying at very low altitudes (100 m and 150 m), we compensated for the low resolution of the camera. In all, 5515 scenes were sampled at 10-s intervals from the video, visually interpreted, and classified. The snow/ice and water cover conditions were also interpreted. The results showed that grassland covers the riverine lowland (RLL) of the Lena River, while the principal form of land cover over the terraces is larch forest (about 61%). There was a remarkable contrast between the left (LBT) and right (RBT) bank terraces of the Lena River, no-forest areas covered 28.8% of the RBT, whereas no-forest areas covered only 13.8% of the LBT. In addition, the LBT had a greater proportion of birch forest than the RBT (15.2% vs 2.5%). The video data over eight days showed that the snow thawed first in the RLL and last in the forested areas of the LBT and RBT. An increase in the area covered by water in the RLL in mid-May was probably due to flooding by the Lena River. Distinguishing insolated from cloud-shadowed scenes of the land surface revealed that the insolation rate was lower over the LBT and RBT than over the RLL. The land-cover database created in this analysis will play an important role as basic, reliable ground-truth information for studies using satellite images. [ABSTRACT FROM AUTHOR]

Published
2004
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33. Global-scale Evaluation of SMAP, SMOS and ASCAT Soil Moisture Products using Triple Collocation.

Author

Chen F, Crow WT, Bindlish R, Colliander A, Burgin MS, Asanuma J, and Aida K

Abstract

Global-scale surface soil moisture products are currently available from multiple remote sensing platforms. Footprint-scale assessments of these products are generally restricted to limited number of densely-instrumented validation sites. However, by taking active and passive soil moisture products together with a third independent soil moisture estimates via land surface modeling, triple collocation (TC) can be applied to estimate the correlation metric of satellite soil moisture products (versus an unknown ground truth) over a quasi-global domain. Here, an assessment of Soil Moisture Active Passive (SMAP), Soil Moisture Ocean Salinity (SMOS) and Advanced SCATterometer (ASCAT) surface soil moisture retrievals via TC is presented. Considering the potential violation of TC error assumptions, the impact of active-passive and satellite-model error cross correlations on the TC-derived inter-comparison results is examined at in situ sites using quadruple collocation analysis. In addition, confidence intervals for the TC-estimated correlation metric are constructed from moving-block bootstrap sampling designed to preserve the temporal persistence of the original (unevenly-sampled) soil moisture time-series. This study is the first to apply TC to obtain a robust global-scale cross-assessment of SMAP, SMOS and ASCAT soil moisture retrieval accuracy in terms of anomaly temporal correlation. Our results confirm the overall advantage of SMAP (with a global average anomaly correlation of 0.76) over SMOS (0.66) and ASCAT (0.63) that has been established in several recent regional, ground-based studies. SMAP is also the best-performing product over the majority of applicable land pixels (52%), although SMOS and ASCAT each shows advantage in distinct geographic regions.

Published
2018
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34. Satellite-based analysis of evapotranspiration and water balance in the grassland ecosystems of Dryland East Asia.

Author

Xia J, Liang S, Chen J, Yuan W, Liu S, Li L, Cai W, Zhang L, Fu Y, Zhao T, Feng J, Ma Z, Ma M, Liu S, Zhou G, Asanuma J, Chen S, Du M, Davaa G, Kato T, Liu Q, Liu S, Li S, Shao C, Tang Y, and Zhao X

Subjects
China, Mongolia, Grassland, Seasons, Spacecraft
Abstract

The regression tree method is used to upscale evapotranspiration (ET) measurements at eddy-covariance (EC) towers to the grassland ecosystems over the Dryland East Asia (DEA). The regression tree model was driven by satellite and meteorology datasets, and explained 82% and 76% of the variations of ET observations in the calibration and validation datasets, respectively. The annual ET estimates ranged from 222.6 to 269.1 mm yr(-1) over the DEA region with an average of 245.8 mm yr(-1) from 1982 through 2009. Ecosystem ET showed decreased trends over 61% of the DEA region during this period, especially in most regions of Mongolia and eastern Inner Mongolia due to decreased precipitation. The increased ET occurred primarily in the western and southern DEA region. Over the entire study area, water balance (the difference between precipitation and ecosystem ET) decreased substantially during the summer and growing season. Precipitation reduction was an important cause for the severe water deficits. The drying trend occurring in the grassland ecosystems of the DEA region can exert profound impacts on a variety of terrestrial ecosystem processes and functions.

Published
2014
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35. An overview of the rangelands atmosphere-hydrosphere-biosphere interaction study experiment in northeastern Asia (RAISE).

Author

Sugita M, Asanuma J, Tsujimura M, Mariko S, Lu M, Kimura F, Azzaya D, and Adyasuren T

Abstract

Intensive observations, analysis and modeling within the framework of the rangelands atmosphere-hydrosphere-biosphere interaction study experiment in northeastern Asia (RAISE) project, have allowed investigations into the hydrologic cycle in the ecotone of forest-steppe, and its relation to atmosphere and ecosystem in the eastern part of Mongolia. In this region, changes in the climate have been reported and a market oriented economy was introduced recently, but their impact on the natural environment is still not well understood. In this RAISE special issue, the outcome is presented of the studies carried out by six groups within RAISE, namely: (1) Land-atmosphere interaction analysis, (2) ecosystem analysis and modeling, (3) hydrologic cycle analysis, (4) climatic modeling, (5) hydrologic modeling, and (6) integration. The results are organized in five relevant categories comprising (i) hydrologic cycle including precipitation, groundwater, and surface water, (ii) hydrologic cycle and ecosystem, (iii) surface-atmosphere interaction, (iv) effect of grazing activities on soils, plant ecosystem and surface fluxes, and (v) future prediction. Comparison with studies on rangelands in other parts of the world, and some future directions of studies still needed in this region are also summarized., (Copyright © 2006 Elsevier B.V. All rights reserved.)

Published
2007
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