Two prized papers, one by Augustin Cauchy in 1815, presented to the French Academy and the other by Hermann Hankel in 1861, presented to Göttingen University, contain major discoveries on vorticity dynamics whose impact is now quickly increasing. Cauchy found a Lagrangian formulation of 3D ideal incompressible flow in terms of three invariants that generalize to three dimensions the now well-known law of conservation of vorticity along fluid particle trajectories for two-dimensional flow. This has very recently been used to prove analyticity in time of fluid particle trajectories for 3D incompressible Euler flow and can be extended to compressible flow, in particular to c...
In this chapter, we consider the 3D incompressible Euler equations. We present classical and recent ...
The growth of vorticity in 3D incompressible Euler turbulence is an issue that has been addressed se...
We introduce many families of explicit solutions to the three dimensional incompressible Euler equat...
The present paper is a companion to the paper by Villone and Rampf (2017), titled “Hermann Hankel's ...
Vorticity dynamics of the three-dimensional incompressible Euler equations is cast into a quaternion...
In fluid mechanics, the vorticity provides a valuable alternative perspective of the behavior of flo...
In this paper we give a brief review of the recent results obtained by the author and his co-authors...
In modern studies in fluid dynamics, it is quite common to describe the velocity and pressure fields...
Geometric Hydrodynamics has flourished ever since the celebrated 1966 paper of V. Arnold. In this pa...
This (Diplom-) thesis deals with the particle trajectories of an incompressible and ideal fluid flow...
We propose an efficient semi-Lagrangian Characteristic Mapping (CM) method for solving the three-dim...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Aeronautics and Astronautics, 1992....
AbstractWe analyze an Eulerian-Lagrangian description of filtered incompressible fluid equations. A ...
We study some of the key quantities arising in the theory of [Arnold "Sur la geometrie differentiell...
We consider incompressible Euler flows in terms of the stream function in two dimensions and the vec...
In this chapter, we consider the 3D incompressible Euler equations. We present classical and recent ...
The growth of vorticity in 3D incompressible Euler turbulence is an issue that has been addressed se...
We introduce many families of explicit solutions to the three dimensional incompressible Euler equat...
The present paper is a companion to the paper by Villone and Rampf (2017), titled “Hermann Hankel's ...
Vorticity dynamics of the three-dimensional incompressible Euler equations is cast into a quaternion...
In fluid mechanics, the vorticity provides a valuable alternative perspective of the behavior of flo...
In this paper we give a brief review of the recent results obtained by the author and his co-authors...
In modern studies in fluid dynamics, it is quite common to describe the velocity and pressure fields...
Geometric Hydrodynamics has flourished ever since the celebrated 1966 paper of V. Arnold. In this pa...
This (Diplom-) thesis deals with the particle trajectories of an incompressible and ideal fluid flow...
We propose an efficient semi-Lagrangian Characteristic Mapping (CM) method for solving the three-dim...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Aeronautics and Astronautics, 1992....
AbstractWe analyze an Eulerian-Lagrangian description of filtered incompressible fluid equations. A ...
We study some of the key quantities arising in the theory of [Arnold "Sur la geometrie differentiell...
We consider incompressible Euler flows in terms of the stream function in two dimensions and the vec...
In this chapter, we consider the 3D incompressible Euler equations. We present classical and recent ...
The growth of vorticity in 3D incompressible Euler turbulence is an issue that has been addressed se...
We introduce many families of explicit solutions to the three dimensional incompressible Euler equat...