Motion of vortices for the extrinsic Ginzburg-Landau flow for vector fields on surfaces
Abstract
We consider the gradient flow of a Ginzburg-Landau functional of the type \[ Fextr(u):=12∫M |D u|g2 + |S u|2g +122(|u|2g-1)2volg \] which is defined for tangent vector fields (here D stands for the covariant derivative) on a closed surface M⊂eqR3 and includes extrinsic effects via the shape operator S induced by the Euclidean embedding of~M. The functional depends on the small parameter >0. When is small it is clear from the structure of the Ginzburg-Landau functional that |u|g ''prefers'' to be close to 1. However, due to the incompatibility for vector fields on M between the Sobolev regularity and the unit norm constraint, when is close to 0, it is expected that a finite number of singular points (called vortices) having non-zero index emerges (when the Euler characteristic is non-zero). This intuitive picture has been made precise in the recent work by R. Ignat \& R. Jerrard [7]. In this paper we are interested the dynamics of vortices generated by Fextr. To this end we study the behavior when 0 of the solutions of the (properly rescaled) gradient flow of Fextr. In the limit 0 we obtain the effective dynamics of the vortices. The dynamics, as expected, is influenced by both the intrinsic and extrinsic properties of the surface M⊂eqR3.
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