Hyperinstantons, the Beltrami equation, and triholomorphic maps

We consider the Beltrami equation for hydrodynamics and we show that its solutions can be viewed as instanton solutions of a more general system of equations. The latter are the equations of motion for an N=2 sigma model on 4‐dimensional worldvolume (which is taken locally HyperKähler) with a 4‐dime...

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Bibliographic Details
Published in:Fortschritte der Physik 2016-02, Vol.64 (2-3), p.151-175
Main Authors: Fré, P., Grassi, P.A., Sorin, A.S.
Format: Article
Language:English
Subjects:
Hyperinstantons
HyperKähler Geometry
Physics
Topology
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Summary:We consider the Beltrami equation for hydrodynamics and we show that its solutions can be viewed as instanton solutions of a more general system of equations. The latter are the equations of motion for an N=2 sigma model on 4‐dimensional worldvolume (which is taken locally HyperKähler) with a 4‐dimensional HyperKähler target space. By means of the 4D twisting procedure originally introduced by Witten for gauge theories and later generalized to 4D sigma‐models by Anselmi and Fré, we show that the equations of motion describe triholomophic maps between the worldvolume and the target space. Therefore, the classification of the solutions to the 3‐dimensional Beltrami equation can be performed by counting the triholomorphic maps. The counting is easily obtained by using several discrete symmetries. Finally, the similarity with holomorphic maps for N=2 sigma on Calabi‐Yau space prompts us to reformulate the problem of the enumeration of triholomorphic maps in terms of a topological sigma model. Considering the Beltrami equation for hydrodynamics it is shown that its solutions can be viewed as instanton solutions of a more general system of equations. The latter are the equations of motion for an N=2 sigma model on 4‐dimensional worldvolume (which is taken locally HyperKähler) with a 4‐dimensional HyperKähler target space. The equations of motion describe triholomophic maps between the worldvolume and the target space. Therefore, the classification of the solutions to the 3‐dimensional Beltrami equation can be performed by counting the triholomorphic maps. Finally, the similarity with holomorphic maps for N=2 sigma on Calabi‐Yau space leads to a reformulation of the problem of the enumeration of triholomorphic maps in terms of a topological sigma model.
ISSN:0015-8208
1521-3978
DOI:10.1002/prop.201500061