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Let's consider in dimension $d\geq 3$ the Newton/riesz potential $f=I_2[g]$ $$ f(x)=\int_{R^d}\frac{1}{|x-y|^{d-2}}g(y)dy, $$ which solves $-\Delta f=g$ (up to positive normalizing constants, which I shall ignore), and assume that $g\in L^q$ for all $q\in[1,2d/(d+2)]$. By the Hardy-Littlewood-Sobolev inequality (or any other variation from [Stein, singular inegrals], [Lieb-Loss, Analysis] etc...) we know that $f\in L^{2d/(d-2)}$, and also $\nabla f\in L^2$ (this is one way to prove the Sobolev embedding $H^1\subset L^{2d/(d-2)}$). If $p=2d/(d+2)$ the conjugated Holder exponent is exactly $p'=\frac{2d}{d-2}$, thus $g\in L^p$, $f\in L^{p'}$ and $fg\in L^1$. Since by definition $-\Delta f=g$ we would expect that $$ \int \underbrace{f}_{\in L^{p'}}\underbrace{g}_{\in L^p}=\int f(-\Delta f)\overset{?}{=}\int |\underbrace{\nabla f}_{\in L^2}|^2. $$

When is the last integration by parts legitimate? With my hypotheses all the above terms are well defined, but is this enough? I seem to remember that there are "exotic" counterexamples...

It seems to me that an approximation argument works fine: if $g_n$ is a sequence of smooth compactly supported functions such that $g_n\to g$ in $L^{2d/(d+2)}$ then by continuity (HLS inequality) we have that $f_n\to f$ in $L^{2d/(d-2)}$ and $\nabla f_n\to \nabla f$ in $L^2$. Since the integration by parts is legitimate for smooth decaying functions then it should pass to the limit... I don't think anything is wrong here, did I miss something or is it really just that easy?

Edit: I just added the approximation argument

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This "integration by parts" is true in larger generality: Let $\mu$ be a measure, $$u(x)=\int\frac{1}{|x-y|^{n-2}}d\mu(y).$$ Then $$\int u(x)d\mu=\int\frac{1}{|x-y|^{n-2}}d\mu(x)d\mu(y)$$ is called the energy of $\mu$. If this is finite, the measure is said of finite energy. Gradient of the potential of such measure is in $L^2$ and your formula holds. Then it is extended to differences of measures (charges) of finite energy. Measures and potentials of finite energy form a Hilbert space with respect to the scalar product $$(\mu,\nu)=\int u(x)d\nu(x).$$

Reference: Landkof, Introduction to modern potential theory, Ch. I, section 4.

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  • $\begingroup$ OK, thank you Alexandre. What if the dimension is now $d=2$ and the Poisson Kernel $-\log|x-y|$? $\endgroup$ Mar 4, 2014 at 14:52
  • $\begingroup$ The case $n=2$ is somewhat special because the kernel is not positive definite. Roughly speaking it becomes positive definite if you restrict to charges of total charge 0 supported on the unit disc. For the details see the same book of Landkof. $\endgroup$ Mar 5, 2014 at 4:53

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