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Riesz transform for $1 leq p le 2$ without Gaussian heat kernel bound

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 Added by Emmanuel Russ
 Publication date 2015
  fields
and research's language is English
 Authors Li Chen




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We study the $L^p$ boundedness of Riesz transform as well as the reverse inequality on Riemannian manifolds and graphs under the volume doubling property and a sub-Gaussian heat kernel upper bound. We prove that the Riesz transform is then bounded on $L^p$ for $1 textless{} p textless{} 2$, which shows that Gaussian estimates of the heat kernel are not a necessary condition for this.In the particular case of Vicsek manifolds and graphs, we show that the reverse inequality does not hold for $1 textless{} p textless{} 2$. This yields a full picture of the ranges of $pin (1,+infty)$ for which respectively the Riesz transform is $L^p$ -bounded and the reverse inequality holds on $L^p$ on such manifolds and graphs. This picture is strikingly different from the Euclidean one.



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