This work proposes a novel framework that integrates diffusion models with physics-informed sequential Monte Carlo (SMC) to generate solutions of partial differential equations (PDEs) that satisfy physical constraints. For the first time, a physics-guided mechanism based on PDE residuals is embedded directly into the stochastic sampling process of the diffusion model, enabling dynamic enforcement of multi-physics and coupled PDE constraints during generation by jointly leveraging observational data and physical laws. Experimental results across multiple benchmark PDE systems and multi-physics coupling problems demonstrate that the proposed method significantly outperforms existing state-of-the-art generative models, achieving lower numerical errors while maintaining high solution fidelity. This approach establishes a new paradigm for scalable, high-accuracy generative PDE solvers.

We introduce a guided stochastic sampling method that augments sampling from diffusion models with physics-based guidance derived from partial differential equation (PDE) residuals and observational constraints, ensuring generated samples remain physically admissible. We embed this sampling procedure within a new Sequential Monte Carlo (SMC) framework, yielding a scalable generative PDE solver. Across multiple benchmark PDE systems as well as multiphysics and interacting PDE systems, our method produces solution fields with lower numerical error than existing state-of-the-art generative methods.