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Lipschitz functions on submanifolds in Heisenberg groups

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 Added by Antoine Julia
 Publication date 2021
  fields
and research's language is English




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We study the behavior of Lipschitz functions on intrinsic $C^1$ submanifolds of Heisenberg groups: our main result is their almost everywhere tangential Pansu differentiability. We also provide two applications: a Lusin-type approximation of Lipschitz functions on $HH$-rectifiable sets, and a coarea formula on $HH$-rectifiable sets that completes the program started in~cite{JNGV}.



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We provide a Rademacher theorem for intrinsically Lipschitz functions $phi:Usubseteq mathbb Wto mathbb L$, where $U$ is a Borel set, $mathbb W$ and $mathbb L$ are complementary subgroups of a Carnot group, where we require that $mathbb L$ is a normal subgroup. Our hypotheses are satisfied for example when $mathbb W$ is a horizontal subgroup. Moreover, we provide an area formula for this class of intrinsically Lipschitz functions.
We continue to develop a program in geometric measure theory that seeks to identify how measures in a space interact with canonical families of sets in the space. In particular, extending a theorem of the first author and R. Schul in Euclidean space, for an arbitrary locally finite Borel measure in an arbitrary Carnot group, we develop tests that identify the part of the measure that is carried by rectifiable curves and the part of the measure that is singular to rectifiable curves. Our main result is entwined with an extension of the Analysts Traveling Salesman Theorem, which characterizes subsets of rectifiable curves in $mathbb{R}^2$ (P. Jones, 1990), in $mathbb{R}^n$ (K. Okikolu, 1992), or in an arbitrary Carnot group (the second author) in terms of local geometric least squares data called Jones $beta$-numbers. In a secondary result, we implement the Garnett-Killip-Schul construction of a doubling measure in $mathbb{R}^n$ that charges a rectifiable curve in an arbitrary complete, quasiconvex, doubling metric space.
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We study the Lipschitz structures on the geodesic compactification of a regular tree, that are preserved by the automorphism group. They are shown to be similar to the compactifications introduced by William Floyd, and a complete description is given.
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