Kinetic models universally describe physical processes relevant to natural and engineering sciences at the level of hyperbolic balance laws characterized by high dimensionality and collision operators modeling particle interaction. Compared to macroscopic fluid models built from PDEs in space and time for averaged quantities, kinetic fluid models are closer to particle descriptions. Their deeper level offers more insight into less understood phenomena, e.g. rarefied gases or compressible turbulence with extreme demands on direct numerical simulation. Resolving small scales requires further mathematical modeling, whereby kinetic models constitute viable candidates to build upon. They bridge scales by their multiscale nature with respect to the ratio of mean free path and characteristic length. For vanishing ratios, reasonable kinetic equations converge towards a macroscopic model such as the compressible Euler equations. Close to the limit, the macroscopic model is sufficiently accurate at reduced cost. However, the multiscale nature of kinetic models may vary locally in space and time in concert with the viability of the corresponding macroscopic model. Requiring the full kinetic model, major numerical challenges are high dimensionality, nonlinearity of physically interesting collision operators, discrete preservation of the asymptotic limit, and stiffness caused by multiple scales. This proposal intends to advance numerical schemes for kinetic models in order to forward the understanding of multiscale behavior and underresolved fluid flow. The overall goal is to devise novel cutting-edge numerical techniques for kinetic models which stand on firm mathematical ground regarding stability, accuracy and asymptotics. To this end, we follow the path of asymptotic preserving schemes to pass from kinetic to macroscopic models on the discrete level and utilize the structure preserving, discretization independent summation-by-parts (SBP) framework owning provable accuracy and stability properties together with a new avenue to implicit-explicit (IMEX) time integration and suitable splittings of the space-discretized equations. Based on micro-macro decompositions, we identify specific stiff terms for implicit time stepping. Understanding the interplay between space and time discretization and between discretized terms with different characteristics is crucial to the design of accurate, stable and asymptotic preserving schemes. New high order asymptotic preserving IMEX upwind SBP schemes will be designed for kinetic equations related to neutron transport, rarefied gases and turbulence. We strive for predictive stability by a unified analysis of the linear and nonlinear stability properties and asymptotic preservation of the newly developed fully discrete schemes, including the interplay between asymptotic preservation and entropy stability in the nonlinear case. Potentially, we will thus enable a deeper understanding of underresolved fluid flow phenomena.

DFG Programme Priority Programmes

Subproject of SPP 2410:  Hyperbolic Balance Laws in Fluid Mechanics: Complexity, Scales, Randomness (CoScaRa)

International Connection Canada

Cooperation Partner Professor David Del Rey Fernandez, Ph.D.