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To be specific, suppose $M$ is a closed oriented manifold, $g$ is a Riemannian metric of $M$. Let $\Delta_g$ be the Laplace-Beltrami operator w.r.t. $g$.

Prove: Suppose $f\in C^\alpha(M)$ satisfies $\int_M f\, dVol_g=0$, then there exists a function $u\in C^{2,\alpha}(M)$ such that $\Delta_g u=f$ in $M$, and $u$ is unique up to plus a constant, here $0<\alpha<1$.

My attempt is that, firstly use $D(u):=\frac{1}{2}\int_M( |\nabla u|^2+fu)dVol_g$ is a convex functional with a lower bound on $W_0^{1,2}(M)$ to show that there exists a weak solution $u\in W^{1,2}(M)$, next use the $L^2$-regularity theory to show that $u\in W^{2,2}(M)$, but I don't know how to improve the regularity of $u$ further. (Actually, I can use the method to prove that if $f$ is $C^\infty$, then $u$ is also $C^\infty$, but I cannot extend this result to $C^\alpha$ case.)

Another attempt is Schauder estimate. However, in Gilbarg and Trudinger's book they assume that $u\in C^{2,\alpha}(M)$ already to get some interior derivative norm bound of $u$, while I don't know how to establish $u\in C^{2,\alpha}(M)$. They give a continuity method to ensure that, but it seems their discussion works for domains in Euclidean space, not for manifolds. Therefore, I want to split the question into coordinate charts, but I failed, because I don't know how to use the condition $\int_M f\, dVol_g=0$ and how to give boundary conditions in every coordinate charts.

Since I'm a novice in PDE, my presentation of the problem might have some errors. Please correct them by comments or answers. Also, any comments or answers are welcome.

Thanks for your help.

Remark: I've already asked this question on math.stackexchange.com, but nobody replied. Maybe this question is not so suitable for MO, but I really want to get an answer.

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  • $\begingroup$ By the way, this is not a Dirichlet problem, since there is no boundary. You can say this is a Poisson equation on a closed manifold. $\endgroup$
    – timur
    Commented Jul 20, 2012 at 17:35
  • $\begingroup$ @timur Thanks for pointing that out~ $\endgroup$
    – Yuchen Liu
    Commented Jul 21, 2012 at 2:46

2 Answers 2

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Careful. C^\infty is not dense in C^{\alpha}. Nonetheless you can first produce an L^2 solution then use Schauder estimates to show that the solution is C^{2,\alpha}. This last step is localizable -- you can multiply by a smooth cutoff function (and use some preliminary estimates to say that the solution is C^2, for example) and transfer to a coordinate chart, then apply the estimates and continuity method in Gilbarg&Trudinger. There are other cleaner ways to proceed: the solution u = G f is given by a pseudodifferential operator of order -2 and it is not hard to prove (see Taylor, Vol. III) that such a psido is bounded from C^\alpha to C^{2,\alpha}.

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  • $\begingroup$ @Rafe Mazzeo: I think my answer is based on your first attempt: math.stackexchange.com/questions/172887/… $\endgroup$
    – Yuchen Liu
    Commented Jul 28, 2012 at 2:49
  • $\begingroup$ what do you mean by "my answer is based on your first attempt"? $\endgroup$
    – YangMills
    Commented Jul 28, 2012 at 16:03
  • $\begingroup$ @YangMills: I mean roughly I use Rafe's method with a little difference: first use $L^2$-theory to find a weak solution $u$, then use Schauder estimate and continuity method to find a $C^{2,\alpha}$ solution $v$ locally, and their difference is a weak solution of $\Delta (u-v)=0$ hence $(u-v)$ is $C^\infty$. Therefore, $u$ is in $C^{2,\alpha}$. $\endgroup$
    – Yuchen Liu
    Commented Jul 29, 2012 at 3:21
  • $\begingroup$ @Rafe: Can you please have a look at my answer? I think I found a way around the density problem. $\endgroup$
    – timur
    Commented Aug 23, 2012 at 1:19
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    $\begingroup$ That is correct, though I guess you need to add a few details that the sequence of solutions $u_j$ which are bounded in $C^{2,\alpha}$ and convergent in $L^2$ (or, say, $C^2$) have limit which lies in $C^{2,\alpha}$. $\endgroup$ Commented Aug 23, 2012 at 2:33
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Elliptic regularity in Hölder spaces is precisely what you need here.

If you want to prove it along the lines you described, using $L^2$-theory, then you can first establish that smooth $f$ leads to smooth solution $u$. Then you approximate $f$ in the $L^2$-norm by smooth functions with uniformly bounded $C^{\alpha}$-norms (this is important as smooth functions are not dense in Hölder spaces), and use the Schauder estimate. It suffices to do everything locally.

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