Estimating the unresolved geophysical processes from resolved geophysical fluid dynamics is the key for improving numerical weather-climate predictions. While data-driven parameterization for unresolved geophysical processes shows potential, most practices fail to capture the diversity of unresolved geophysical processes that agree with resolved geophysical fluid state. This pitfall undermines the likelihood or severity of simulated weather extremes, and erodes the fidelity of climate projections. We propose the criteria of READS (Realism, Efficiency, Adaptability, Diversity, Sharpness) for generative models to yield reasonable stochastic parameterization. We introduce probabilistic diffusion model, a non-equilibrium thermodynamics inspired deep generative modeling approach, to better meet these criteria. Using a case example of numerical precipitation estimation, we demonstrate the advantage of the proposed methodology in quickly delivering diverse and faithful estimates for the target unresolved process, as compared to other popular data-driven deterministic and stochastic methods (UNet, variational autoencoder, generative adversarial net), as well as dynamical downscaling method (WRF). We conclude that generative models, in particular, probabilistic diffusion model, can significantly enhance the representation of unresolved geophysical processes in numerical weather-climate predictions.

We present a novel Overlapped Cloud Motion Vectors (OCMVs) deriving algorithm using the Himawari-8 satellite. A multi-layer Cloud Top Heights (CTHs) retrieving model based on multi-spectral observed radiances is constructed using neural networks to reduce the substantial uncertainty of CMVs over multi-layer clouds. The retrieved CTHs are assigned to upper ice and lower water cloud layers, then they are used as respective tracers for deriving OCMVs based on an optical flow algorithm. OCMVs reveal the asymmetric kinematic structure of Typhoon Mulan, particularly in the typhoon’s inner-core. The vortex center of lower water CMVs is significantly closer to the typhoon center than that of the upper ice CMVs. Additionally, the direction of CMVs in the lower inner-core show excellent agreement with dropsonde observations. This marks the first time that a geostationary satellite successfully captured the lower layer CMVs of typhoons, providing a valuable reference for the typhoon center identification.