Observable Field Theory & Its Application in Regularization of Shocks, Turbulence & Two-Phase Flows ~ by Professor Kamran Mohseni

Abstract: Turbulence, shock formation, and sharp interfaces in inviscid flows are prone to high wavenumber mode generations. This continuous generation of high wavemodes results in a cascade of energy to an ever smaller scales in turbulence, creation of shocks in compressible flows, and generation of sharp interfaces in two-phase flows which I dub as wavenumber-infinity irregularity. Traditionally, this high wavenumber irregularity is remedied by the addition of a Laplacian term (viscous term) in both compressible and incompressible flows. In this talk, I introduce the concept of observability of field quantities and the consequence of that on the Gauss divergence theorem and Stokes curl theorem. An observable Gauss and Stokes theorem are then derived. These theorems allow the derivation of `regularized’ field quantities from basic conservation laws. To this end, `observable’ Euler and Navier-Stokes equations are formally derived. It is expected that these equations simultaneously regularize shocks, turbulence, and sharp interfaces. Several theoretical results (including existence, uniqueness, convergence to entropy solutions, and observable Lie bracket) and numerical simulations (including 3D turbulence, shock-turbulence interaction, and two-phase flows) will be presented and compared with existing numerical methods.

Biosketch: Kamran Mohseni received his PhD in Mechanical Engineering from Caltech in 2000. After a year of postdoc in control and dynamical systems at Caltech, he joined the Aerospace Engineering Department at the University of Colorado in Boulder in 2001. He moved to the University of Florida in 2011 as the Bushnell Endowed chair in both MAE and ECE departments.

Date/Time:
Date(s) - Dec 14, 2017
4:00 pm - 5:00 pm

Location:
38-138 Engineering IV
420 Westwood Plaza Los Angeles CA 90095