Air quality degradations caused by fine particulate matter (PM2.5) can lead to various health problems, and accurate PM2.5 data are critical for managing the environment and ensuring public health. Radiation signals collected by nighttime light (NTL) remote sensing satellites are influenced by PM2.5 concentrations, and thus, incorporating NTL imagery in statistical models has been widely used to predict PM2.5 concentrations. However, scarce work has been carried out with new generation NTL data from the LJ1-01 satellite, which has a fine spatial resolution and wide measurement range. In this study, we integrated satellite observation data, and meteorological data to construct five models based on the geographically weighted regression (GWR) to validate the feasibility of LJ1-01/NPP-VIIRS in MODIS AOD based PM2.5 prediction in the Beijing-Tianjin-Hebei (BTH) region. The models were validated by cross-validation method. The results showed that the addition of NTL information could improve the performance of the PM2.5 prediction model. The seasonal R 2 with NTL in AOD-PM2.5 model have improved by 5.07%, 4.50%, 2.95%, 2.56% in model fitting and 1.20%, 1.75%, 2.20%, 4.41% in crossvalidation. Furthermore, The LJ1-01 NTL data revealed additional details and improved the prediction accuracy, compared with the NPP-VIIRS in AOD-PM2.5 model, the seasonal R 2 with LJ1-01 in AOD-PM2.5 model increased by 1.16%, 1.79%, 0.76%, 1.15% in model fitting and 1.04%, 0.85%, 0.78%, 1.37% in cross-validation. Thus, Our findings indicate that LJ1-01 NTL data have potential for predicting PM2.5 and that they could constitute a useful supplemental data source for estimating ground-level PM2.5 distributions.