N: 90 S: -90 E: 180 W: -180
Description
The Moderate Resolution Imaging Spectroradiometer (MODIS) MCD43A3 Version 6.1 Albedo Model dataset is produced daily using 16 days of Terra and Aqua MODIS data at 500 meter (m) resolution. Data are temporally weighted to the ninth day of the 16 day which is reflected in the Julian date in the file name.
Users are urged to use the band specific quality flags to isolate the highest quality full inversion results for their own science applications as described in the User Guide.
The MCD43A3 provides black-sky albedo (directional hemispherical reflectance) and white-sky albedo (bihemispherical reflectance) data at local solar noon for MODIS bands 1 through 7 and the visible, near infrared (NIR), and shortwave bands. Along with the albedo layers are the simplified mandatory quality layers for each of the 10 bands. Essential quality information provided in the corresponding MCD43A2 data file should be consulted when using this product.
Known Issues
- For complete information about known issues please refer to the MODIS/VIIRS Land Quality Assessment website.
Version Description
Product Summary
Citation
Citation is critically important for dataset documentation and discovery. This dataset is openly shared, without restriction, in accordance with the EOSDIS Data Use and Citation Guidance.
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File Naming Convention
The file name begins with the Product Short Name (MCD43A3) followed by the Julian Date of Acquisition formatted as AYYYYDDD (A2025212), the Tile Identifier which is horizontal tile and vertical tile provided as hXXvYY (h11v12), the Version of the data collection (061), the Julian Date and Time of Production designated as YYYYDDDHHMMSS (2025221032740), and the Data Format (hdf).
Documents
USER'S GUIDE
ALGORITHM THEORETICAL BASIS DOCUMENT (ATBD)
PRODUCT QUALITY ASSESSMENT
SCIENCE DATA PRODUCT VALIDATION
Publications Citing This Dataset
| Title | Year Sort ascending | Author | Topic |
|---|---|---|---|
| Recent Widespread Deceleration of Global Surface Urban Heat Islands | Zhan, Wenfeng, Li, Long, Chakraborty, T. C., Hu, Leiqiu, Wang, Dazhong, Liao, Weilin, Wang, Shasha, Du, Huilin, Huang, Fan, Wang, Chunli, Liu, Zihan, Li, Manchun | Albedo, Anisotropy, Land Use/Land Cover Classification, Land Surface Temperature, Emissivity, Aerosol Optical Depth/Thickness, Vegetation Index, Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI) | |
| Radiative forcing reduced by early twenty-first century increase in land albedo | Hou, Zhengyang, Zhang, Liqiang, Peng, Jingjing, Forzieri, Giovanni, Jia, Aolin, Xiao, Zhiqiang, Qu, Ying, Lin, Jintai, Ji, Duoying, Zhu, Zidong, Yao, Xin, Peng, Shuwen, Zhao, Lanpu, Fan, Wenjie, Wu, Zhaocong, Geng, Hao, Wang, Qihao, Zhou, Chenghu, Liu, Suhong, Zhang, Liangpei | Land Use/Land Cover Classification, Reflectance, Albedo, Anisotropy, Albedo, Snow Cover | |
| On the added value of sequential deep learning for the upscaling of evapotranspiration | Kraft, Basil, Nelson, Jacob A., Walther, Sophia, Gans, Fabian, Weber, Ulrich, Duveiller, Gregory, Reichstein, Markus, Zhang, Weijie, Ruwurm, Marc, Tuia, Devis, Korner, Marco, Hamdi, Zayd, Jung, Martin | Reflectance, Anisotropy, Land Surface Temperature, Emissivity, Albedo | |
| Seasonality and Albedo Dependence of Cloud Radiative Forcing in the Upper Colorado River Basin | Rudisill, William, Feldman, Daniel, Cox, Christopher J., Riihimaki, Laura, Sedlar, Joseph | Albedo, Anisotropy | |
| Spatially generalizable bias correction of satellite solar radiation for | Damiani, A., Ishizaki, N.N., Watanabe, T., Tamaki, Y., Cordero, R.R., Feron, S., Irie, H. | Albedo, Anisotropy | |
| Study of the impact of climate change on tourism activities using remote sensing in the Carpathian region | DEPUTAT, Mykola, TERLETSKA, Khrystyna, ZHUPNYK, Vasyl, HORISHEVSKYI, Pavlo, KASIYANCHUK, Dmytro | Snow Cover, Albedo, Anisotropy | |
| Two Decades of FireInduced Albedo Change and Associated ShortWave Radiative Effect Over SubSaharan Africa | Flegrova, Michaela, Brindley, Helen | Land Use/Land Cover Classification, Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Albedo, Anisotropy, Reflectance | |
| Two-stage downscaling and correction cascade learning framework for | Li, Jie, Wei, Yingtao, Lin, Liupeng, Yuan, Qiangqiang, Shen, Huanfeng | Brightness Temperature, Surface Soil Moisture, Vegetation Index, Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), Land Surface Temperature, Emissivity, Precipitation, Precipitation Amount, Precipitation Rate, Snow, Rain, Albedo, Anisotropy | |
| The surface mass balance and near-surface climate of the Antarctic ice | van Dalum, Christiaan T., van de Berg, Willem Jan, van den Broeke, Michiel R., van Tiggelen, Maurice | Albedo, Anisotropy, Reflectance | |
| Tourism Pressure and Vegetation Dynamics in the Carpathian Mountains | Kasiyanchuk, Dmytro | Albedo, Anisotropy | |
| Divergent Seasonal Biophysical Effects Induced by the Three Gorges | Li, Hongbin, Wang, Weiguang, Liu, Guoshuai, Castelli, Fabio, Forzieri, Giovanni | Land Use/Land Cover Classification, Land Surface Temperature, Emissivity, Evapotranspiration, Latent Heat Flux, Albedo, Anisotropy | |
| Elevation Correction of Forest Biogeophysical Cooling Effect in China | Bai, Tingting, Song, Yongze, Li, Tong, Zheng, Jinxiu, Zhu, Kai | Evapotranspiration, Photosynthesis, Primary Production, Latent Heat Flux, Land Surface Temperature, Emissivity, Leaf Characteristics, Photosynthetically Active Radiation, Leaf Area Index (LAI), Fraction Of Absorbed Photosynthetically Active Radiation (fapar), Albedo, Anisotropy | |
| AI-Based Downscaling of MODIS LST Using SRDA-Net Model for High-Resolution Data Generation | Ma, Hongxia, Mao, Kebiao, Yuan, Zijin, Xu, Longhao, Shi, Jiancheng, Guo, Zhonghua, Qin, Zhihao | Reflectance, Land Surface Temperature, Emissivity, Albedo, Anisotropy, Land Use/Land Cover Classification | |
| A Spatial Hybrid Model for Crop Yield Prediction in Western Australia | Ibrahim, Muhammad, Singh, Balwinder, Pires, Rodrigo, Easton, Julia, Tareque, Hasnein | Albedo, Anisotropy | |
| A strategy to estimate daily shortwave downward radiation in rugged regions from a few satellite observations | Xian, Yuyang, Wang, Tianxing, Du, Yihan, Yu, Pei, Letu, Husi | Albedo, Anisotropy | |
| Assessing midsummer snow-free land surface albedo variability across multiple Arctic sites using the Harmonized Landsat and Sentinel-2 product | Gottuk, Jannika, Stuenzi, Simone M., Runge, Alexandra, Boike, Julia | Reflectance, Albedo, Anisotropy | |
| Climate change dominates recent increase in streamflow in the Yellow River Basin | Huang, Zhen, Tang, Zixuan, Tian, Jing, Zhang, Xuanze, Ma, Ning, Bai, Xinli, Zhang, Yongqiang | Albedo, Anisotropy | |
| Brief communication: Improving lake ice modeling in ORCHIDEE-FLake model using MODIS albedo data | Titus, Zacharie, Cuynet, Amelie, Salmon, Elodie, Ottle, Catherine | Albedo, Anisotropy | |
| Estimating GPP in China using different site-level datasets, vegetation classification and vegetation indices | Xu, Jiahui, Chen, Tiexi, Chen, Xin, Zhou, Shengjie, Gu, Zhe, Li, Wenhui, Cui, Yingying, Wang, Shengzhen, Liu, Shuci | Photosynthetically Active Radiation, Leaf Area Index (LAI), Leaf Characteristics, Fraction Of Absorbed Photosynthetically Active Radiation (fapar), Reflectance, Albedo, Anisotropy, Land Use/Land Cover Classification | |
| Enhancing prediction of wildfire occurrence and behavior in Alaska using | Ahajjam, A., Allgaier, M., Chance, R., Chukwuemeka, E., Putkonen, J., Pasch, T. | Land Use/Land Cover Classification, Vegetation Index, Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), Land Surface Temperature, Emissivity, Albedo, Anisotropy | |
| Evaluation of the performance of multiple reanalysis forcing data in | Xie, Yuxuan, Kong, Dongdong, Zhang, Yongqiang, Zhong, Yulong, Ma, Ning, Gong, Rouyan, Ci, Hui, Xiao, Mingzhong, Gu, Xihui | Leaf Area Index (LAI), Fraction Of Absorbed Photosynthetically Active Radiation (fapar), Land Surface Temperature, Emissivity, Albedo, Anisotropy, Land Use/Land Cover Classification | |
| Global non-uniformity in biophysical surface temperature responses to cropland expansion over non-forest vegetation | Si, Menglin, Li, Zhao-Liang, Liu, Xiangyang, Li, Yitao, Leng, Pei, Tang, Bo-Hui, Tang, Ronglin, Duan, Si-Bo, Liu, Meng, Zhou, Chenghu | Evapotranspiration, Latent Heat Flux, Albedo, Anisotropy | |
| Megagrazer loss drives complex landscape-scale biophysical cascades | Hyvarinen, Olli, te Beest, Mariska, le Roux, Elizabeth, Kerley, Graham I H, Buitenwerf, Robert, Druce, Dave J, Chen, Jiquan, Rapp, Linda, Fernandes, Joana, Cromsigt, Joris P G M | Canopy Characteristics, Evergreen Vegetation, Crown, Deciduous Vegetation, Leaf Characteristics, Vegetation Cover, Land Use/Land Cover Classification, Albedo, Anisotropy, Reflectance | |
| Impacts of forest cover change on local temperature in Yangtze River Delta and Pearl River Delta urban agglomerations of China | Liu, Qing, Shen, Wenjuan, Wang, Tongyu, He, Jiaying, Cao, Pingting, Sun, Tianyi, Zhang, Ying, Ye, Wenjing, Huang, Chengquan | Albedo, Anisotropy, Evapotranspiration, Latent Heat Flux, Land Surface Temperature, Emissivity, Reflectance | |
| Incorporating changes in land surface temperature improves BESS | Lu, Xiaoman, Guan, Kaiyu, Jiang, Chongya, Gao, Lun, Wang, Sheng, Zhang, Jiaying | Albedo, Anisotropy, Fraction Of Absorbed Photosynthetically Active Radiation (fapar), Leaf Area Index (LAI), Precipitation, Precipitation Amount, Precipitation Rate, Snow, Rain, Leaf Characteristics, Photosynthetically Active Radiation, Reflectance |