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Register a new userA sharp rearrangement principle in Fourier space and symmetry results for PDEs with arbitrary order
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We prove sharp inequalities for the symmetric-decreasing rearrangement in Fourier space of functions in $mathbb{R}^d$. Our main result can be applied to a general class of (pseudo-)differential operators in $mathbb{R}^d$ of arbitrary order with radial Fourier multipliers. For example, we can take any positive power of the Laplacian $(-Delta)^s$ with $s> 0$ and, in particular, any polyharmonic operator $(-Delta)^m$ with integer $m geq 1$. As applications, we prove radial symmetry and real-valuedness (up to trivial symmetries) of optimizers for: i) Gagliardo-Nirenberg inequalities with derivatives of arbitrary order, ii) ground states for bi- and polyharmonic NLS, and iii) Adams-Moser-Trudinger type inequalities for $H^{d/2}(mathbb{R}^d)$ in any dimension $d geq 1$. As a technical key result, we solve a phase retrieval problem for the Fourier transform in $mathbb{R}^d$. To achieve this, we classify the case of equality in the corresponding Hardy-Littlewood majorant problem for the Fourier transform in $mathbb{R}^d$.
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We study ground state solutions for linear and nonlinear elliptic PDEs in $mathbb{R}^n$ with (pseudo-)differential operators of arbitrary order. We prove a general symmetry result in the nonlinear case as well as a uniqueness result for ground states in the linear case. In particular, we can deal with problems (e.,g. higher order PDEs) that cannot be tackled by usual methods such as maximum principles, moving planes, or Polya--Szego inequalities. Instead, we use arguments based on the Fourier transform and we apply a rigidity result for the Hardy-Littlewood majorant problem in $mathbb{R}^n$ recently obtained by the last two authors of the present paper.
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