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Pseudoconvexity for the Special Lagrangian Potential Equation

Analysis of PDEs 2020-06-23 v4 Differential Geometry

Abstract

The Special Lagrangian Potential Equation for a function uu on a domain ΩRn\Omega\subset {\bf R}^n is given by tr{arctan(D2u)}=θ{\rm tr}\{\arctan(D^2 \,u) \} = \theta for a contant θ(nπ2,nπ2)\theta \in (-n {\pi\over 2}, n {\pi\over 2}). For C2C^2 solutions the graph of DuDu in Ω×Rn\Omega\times {\bf R}^n is a special Lagrangian submanfold. Much has been understood about the Dirichlet problem for this equation, but the existence result relies on explicitly computing the associated boundary conditions (or, otherwise said, computing the pseudo-convexity for the associated potential theory). This is done in this paper, and the answer is interesting. The result carries over to many related equations -- for example, those obtained by taking karctanλkg=θ\sum_k \arctan\, \lambda_k^{{\mathfrak g}} = \theta where g:Sym2(Rn)R{{\mathfrak g}} : {\rm Sym}^2({\bf R}^n)\to {\bf R} is a Garding-Dirichlet polynomial which is hyperbolic with respect to the identity. A particular example of this is the deformed Hermitian-Yang-Mills equation which appears in mirror symmetry. Another example is jarctanκj=θ\sum_j \arctan \kappa_j = \theta where κ1,...,κn\kappa_1, ... , \kappa_n are the principal curvatures of the graph of uu in Ω×R\Omega\times {\bf R}. We also discuss the inhomogeneous Dirichlet Problem tr{arctan(Dx2u)}=ψ(x){\rm tr}\{\arctan(D^2_x \,u)\} = \psi(x) where ψ:Ω(nπ2,nπ2)\psi : \overline{\Omega}\to (-n {\pi\over 2}, n {\pi\over 2}). This equation has the feature that the pull-back of ψ\psi to the Lagrangian submanifold Lgraph(Du)L\equiv {\rm graph}(Du) is the phase function θ\theta of the tangent spaces of LL. On LL it satisfies the equation ψ=JH\nabla \psi = -JH where HH is the mean curvature vector field of LL.

Keywords

Cite

@article{arxiv.2001.09818,
  title  = {Pseudoconvexity for the Special Lagrangian Potential Equation},
  author = {F. Reese Harvey and H. Blaine Lawson},
  journal= {arXiv preprint arXiv:2001.09818},
  year   = {2020}
}

Comments

Several things were added to the paper. More examples were given, some new results were proved, and the historical discussion was expanded

R2 v1 2026-06-23T13:21:45.399Z