Matrix Fluid Dynamics

The paper reports the recent results on application and extension of the matrix formulation of lagrangian hydrodynamic equations. The matrix approach is based on the notion of continuous deformation of infinitesimal material elements and treats the Jacobi matrix of their derivatives with respect to lagrangian variables as the fundamental quantity completely describing fluid motion. We begin with brief review of the governing matrix equation (for the detailed discussion see Yakubovich, E.I. & Zenkovich, D.A. 2001 Matrix approach to Lagrangian fluid dynamics. J. Fluid Mech. vol. 443, 167-196). The new general relationship between two- and three-dimensional solutions of the matrix equations is then found and applied to 3-D generalization of plane 'Ptolemaic' vortices. As a result, families of non-stationary swirling vortices and of stretched vortices in an axisymmetric strain are constructed and studied. The set of matrix equations is extended to include the effect of viscosity by incorporating an evolution equation for the Cauchy invariants, which represents a lagrangian analogue of the Helmholtz equation for a viscous fluid.