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Abstract We consider integral area-minimizing 2-dimensional currents$$T$$ in$$U\subset \mathbf {R}^{2+n}$$ with$$\partial T = Q\left [\!\![{\Gamma }\right ]\!\!]$$ , where$$Q\in \mathbf {N} \setminus \{0\}$$ and$$\Gamma $$ is sufficiently smooth. We prove that, if$$q\in \Gamma $$ is a point where the density of$$T$$ is strictly below$$\frac{Q+1}{2}$$ , then the current is regular at$$q$$ . The regularity is understood in the following sense: there is a neighborhood of$$q$$ in which$$T$$ consists of a finite number of regular minimal submanifolds meeting transversally at$$\Gamma $$ (and counted with the appropriate integer multiplicity). In view of well-known examples, our result is optimal, and it is the first nontrivial generalization of a classical theorem of Allard for$$Q=1$$ . As a corollary, if$$\Omega \subset \mathbf {R}^{2+n}$$ is a bounded uniformly convex set and$$\Gamma \subset \partial \Omega $$ a smooth 1-dimensional closed submanifold, then any area-minimizing current$$T$$ with$$\partial T = Q \left [\!\![{\Gamma }\right ]\!\!]$$ is regular in a neighborhood of $$\Gamma $$ .
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Chaos in Stochastic 2d Galerkin-Navier–Stokes
Abstract We prove that all Galerkin truncations of the 2d stochastic Navier–Stokes equations in vorticity form on any rectangular torus subjected to hypoelliptic, additive stochastic forcing are chaotic at sufficiently small viscosity, provided the frequency truncation satisfies$$N\ge 392$$ . By “chaotic” we mean having a strictly positive Lyapunov exponent, i.e. almost-sure asymptotic exponential growth of the derivative with respect to generic initial conditions. A sufficient condition for such results was derived in previous joint work with Alex Blumenthal which reduces the question to the non-degeneracy of a matrix Lie algebra implying Hörmander’s condition for the Markov process lifted to the sphere bundle (projective hypoellipticity). The purpose of this work is to reformulate this condition to be more amenable for Galerkin truncations of PDEs and then to verify this condition using (a) a reduction to genericity properties of a diagonal sub-algebra inspired by the root space decomposition of semi-simple Lie algebras and (b) computational algebraic geometry executed by Maple in exact rational arithmetic. Note that even though we use a computer assisted proof, the result is valid for all aspect ratios and all sufficiently high dimensional truncations; in fact, certain steps simplify in the formal infinite dimensional limit.
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- PAR ID:
- 10500841
- Publisher / Repository:
- Springer Science + Business Media
- Date Published:
- Journal Name:
- Communications in Mathematical Physics
- Volume:
- 405
- Issue:
- 4
- ISSN:
- 0010-3616
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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