Your search keyword '"Mengjia Wang"' showing total 5 results

1. Global Scale IB AMSR2 Vegetation Optical Depth at X-Band

Author

Lei Fan, Robert Fernandez-Moran, Philippe Ciais, Rui Sun, Xiaojun Li, Xiangzhuo Liu, Christophe Moisy, Mengjia Wang, Jean-Pierre Wigneron, Frédéric Frappart, Amen Al-Yaari, Hongliang Ma, and Zanpin Xing

Subjects

Biomass (ecology), Scale (ratio), Biosphere, Environmental science, Vegetation, Leaf area index, Albedo, Atmospheric sciences, Water content, Normalized Difference Vegetation Index

Abstract

Vegetation Optical Depth (VOD) plays an increasingly important role in studying global carbon, water and energy transformation [1], [2]. This study explores the performance of the X-MEB (X-band microwave emission of the biosphere) model at global scale. Similar to the L-MEB model, the X-MEB model, built by INRAE (Institut national de recherche pour l'agriculture, l'alimentation et l'environnement) Bordeaux, aims to retrieve VOD (referred to as IB X-VOD) at X-band. To avoid the ill-posed problem caused by retrieving two parameters of interest (soil moisture (SM) and VOD) from mono-angular and dual-polarized observations (AMSR2), which are strongly correlated, we used the ERA5 SM product as an input to the X-MEB inversion. At a first step, we produced global IB X-VOD in year 2015 using the parameters (soil roughness and effective scattering albedo) calibrated in the African continent and evaluated the retrieved X-VOD with three vegetation parameters including Above-Ground Biomass (AGB), Leaf Area Index (LAI) and Normalized Difference Vegetation Index (NDVI). The evaluation results indicate X-MEB model has a great potential for global VOD retrievals from AMSR2 satellite data.

Published

2021

2. Global Long-Term Brightness Temperature Record from L-Band SMOS and Smap Observations

Author

Xiangzhuo Liu, Zanping Xing, Gabrielle De Lannoy, Lei Fan, Christophe Moisy, Frédéric Frappart, Xiaojun Li, Amen Al-Yaari, J.-P. Wigncron, Mengjia Wang, Honagliang Ma, Robert Fernandez-Moran, and Alexandra G. Konings

Subjects

Vegetation optical depth, L band, Data continuity, Brightness temperature, Environmental science, Microwave remote sensing, Optical polarization, Sensor fusion, Term (time), Remote sensing

Abstract

Passive microwave remote sensing observations at L-band provide key and global information on surface soil moisture (SM) and vegetation optical depth (VOD), which are related to the Earth water and carbon cycles. Only two spaceborne L-band sensors are currently operating: SMOS, launched end of 2009 and thus providing now a 11-year global dataset and SMAP, launched beginning of 2015. To ensure SM and L-VOD data continuity in the event of failure of one of the space-borne SMOS or SMAP sensors, we developed a consistent brightness temperature (TB) record by first producing consistent 40° SMOS and SMAP TB estimates based on SMOS-IC and SMAP enhanced data resp., and then fusing them via linear fusion method. We found that SMOS and SMAP TB are strongly correlated (R > 0.90 over most of the globe) but present a small bias at both the horizontal and vertical polarizations. The preliminary evaluation results show that this bias can be adjusted using a linear fit, but further evaluation procedures are still needed. In the near future, we will develop a long-term time series of SM and L-VOD products based on this merged SMOS-SMAP TB record.

Published

2021

3. Interannual Variability of Biomass (SMOS Vegetation Optical Depth) Over the Contiguous United States

Author

Jean-Pierre Wigneron, Christophe Moisy, Xiaojun Li, Robert Fernandez-Moran, Frédéric Frappart, Hongliang Ma, Agnès Ducharne, Zanping Xing, Lei Fan, Xiangzhuo Liu, Mengjia Wang, and Amen Al-Yaari

Subjects

Biomass (ecology), Vegetation optical depth, Correlation coefficient, food and beverages, Environmental science, Precipitation, Vegetation, Herbaceous plant, Atmospheric sciences, complex mixtures

Abstract

Interannual variability in biomass represented by SMOS vegetation optical depth (VOD) and precipitation was assessed over the Contiguous United States. The greatest interannual variability in both VOD and precipitation occurred in shrubs and herbaceous (grasslands), with forests the least variable. At a continental scale, VOD was strongly correlated with annual precipitation. Results showed a significant correlation coefficient (∼ 0.93) between interannual variability of precipitation and biomass, indicating that the interannual variability of precipitation could be a good predictor of the interannual variability of biomass.

Published

2021

4. Assessment of Four Model-Based Surface Soil Temperature Products Unsing Global Dense in Situ Observations

Author

Frédéric Frappart, Amen Al-Yaari, Jean-Pierre Wigneron, Xiangzhuo Liu, Jiangyuan Zeng, Nengcheng Chen, Lei Fan, Mengjia Wang, Hongliang Ma, Xiaojun Li, and Xiang Zhang

Subjects

In situ, Soil temperature, Meteorology, Absolute bias, Retrospective analysis, Range (statistics), Environmental science, Hydrometeorology, Negative bias, System model

Abstract

Assessment of the model-based surface soil temperature (ST) products is very important for hydrometeorological and ecological applications, as well as model refinements. Distinguished from previous regional validations using only in situ observations from sparse networks, this study focused on the evaluation of model-based ST products by considering ground observations from 15 dense networks worldwide from April 2015 to December 2017 covering a wide range of ground conditions. Four model-based ST products were selected for the assessment, including the Modern-Era Retrospective Analysis for Research and Applications, version 2 (MERRA-2), the Goddard Earth Observing System Model version 5 Forward Processing (GEOS-5 FP), the ERA-Interim and its successor, the newly developed ERA5. The results indicate the GEOS-5 ST product slightly outperforms other ST products by showing an averaged ubRMSD of 1.84 K. All model-based ST products underestimate in situ ST with a negative bias. All four model-based ST products are demonstrated to well capture the temporal trends of ground observations with very promising $R$ values larger than 0.97. The ERA5 shows visible improvements compared to its predecessor ERA-Interim by exhibiting smaller ubRMSD, absolute bias and larger $R$ values. These findings are expected to provide useful suggestions for the enhancement and specific usage of the model-based ST products.

Published

2021

5. Towards a Better Understanding of Effective Temperature Modelling in the SMOS-IC Retrieval Algorithm

Author

Jean-Pierre Wigneron, Xiaojun Li, Maria Piles, Lei Fan, Roberto Fernandez-Moran, Gustau Camps-Valls, Amen Al-Yaari, Mengjia Wang, and Luis Gómez-Chova

Subjects

Canopy, Radiometer, Microwave radiometer, Weather forecasting, Environmental science, Context (language use), Satellite, Vegetation, computer.software_genre, Water content, computer, Remote sensing

Abstract

The present study focuses on retrieving soil and canopy temperatures, which are key parameters to estimate soil moisture and vegetation optical depth from multi-frequency microwaves information. Several retrieval algorithms assume that canopy and vegetation temperatures are similar in thermal equilibrium conditions, while others separate their contributions, as SMOS-IC, one of the consolidated retrieval algorithms for the Soil Moisture and Ocean Salinity (SMOS) satellite mission. Soil and canopy temperatures in SMOS-IC are modelled from the ECMWF (European Centre for Medium-Range Weather Forecasts) centre. Both SMOS and the Soil Moisture Active Passive (SMAP) missions are currently the only passive L-band (1.4 GHz) missions in operation, but their lifetime is limited. In this context, the upcoming Copernicus Imaging Microwave Radiometer (CIMR) mission will provide continuity on L-band measurements with complementary information in a range of microwave frequencies, from 1.4 to 36.5 GHz. This study uses in situ soil moisture information from the International Soil Moisture Network (ISMN) as input in the SMOS-IC algorithm to retrieve vegetation optical depth (VOD) and soil/canopy effective temperature (T GC ). The retrieved effective temperature is then compared with modelled temperatures from ECMWF and with data from the Advanced Microwave Scanning Radiometer 2 (AMSR2), which acquires the higher frequency bands (C, X, K a , and K u ) present in the future CIMR mission. Results confirm the potential of all high-frequency bands to estimate T GC , with C and X-bands being the most correlated. This study is a first approach to evaluate how microwave multi-frequency information can help modelling soil and canopy temperatures in the SMOS-IC retrieval algorithm, from which the upcoming CIMR mission may benefit.

Published

2021