4.7 Article

A Physical-Based Framework for Estimating the Hourly All-Weather Land Surface Temperature by Synchronizing Geostationary Satellite Observations and Land Surface Model Simulations

Journal

Publisher

IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TGRS.2022.3222563

Keywords

Advanced Himawari imager (AHI); data assimilation; ensemble Kalman filter (EnKF); land surface temperature (LST); Noah land surface model with multiple parameterization (Noah-MP); passive microwave (PMW)

Funding

  1. Second Tibetan Plateau Scientific Expedition and Research Program (STEP [2019QZKK0206]
  2. National Natural Science Foundation of China [42192581, 42090012, 42071308]

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In this study, a physical-based framework for generating high-frequency all-weather land surface temperature (LST) data was developed by synchronizing geostationary satellite thermal-infrared observations and land surface model simulations. The framework consisted of three parts: retrieval of clear-sky LST, assimilation of observations into the land surface model, and fusion of retrieved LST and assimilated LST using an ensemble Kalman filter algorithm. The proposed framework was shown to be capable of obtaining accurate high-frequency all-weather LST data.
The high-frequency all-weather land surface temperature (LST) product generated from the thermal-infrared (TIR) observations of the geostationary meteorological satellite is of great significance to study the diurnal variations in the LST and the land surface energy balance. However, the TIR sensor cannot penetrate the clouds and obtain the desired LST under cloudy conditions. In this study, we developed a physical-based framework for generating high-frequency (hourly) all-weather LST data by synchronizing geostationary satellite TIR observations and simulations of the land surface model (LSM). There are three parts to the developed framework. First, the clear-sky LST was retrieved from the Advanced Himawari Imager (AHI) onboard the geostationary satellite Himawari-8 using our newly developed temperature and emissivity separation algorithm. Second, the Advanced Microwave Scanning Radiometer 2 (AMSR2) observations were assimilated into the Noah land surface model with multiple parameterization (Noah-MP) options' model to generate the all-weather LST. Finally, the retrieved clear-sky AHI LST and Noah-MP assimilated LST were fused using the ensemble Kalman filter (EnKF) algorithm. In situ measurements from three networks were collected to evaluate the Noah-MP assimilated LST and EnKF fused LST. The bias/RMSE of the Noah-MP assimilated LST and EnKF fused LST were-0.16/3.01 K and 0.15/2.68 K, respectively, under all-weather conditions. Compared to the Noah-MP free-run LST, the absolute values of the bias were reduced by 0.64 K and 0.68 K for the Noah-MP assimilated LST and EnKF fused LST, while the RMSEs were reduced by 0.33 K and 0.65 K, respectively. In addition, the spatial distribution of EnKF fused LST was in good agreement with the retrieved clear-sky AHI LST. The proposed framework in this study was demonstrated to be capable of obtaining accurate high-frequency (hourly) all-weather LST data.

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