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geometric analysis

Ricci Flow and Volume Renormalizability

arXiv:1607.08558 · doi:10.3842/SIGMA.2019.057

summary

The paper shows that even asymptotic expansions of conformally compact asymptotically hyperbolic metrics are preserved under normalized Ricci flow and derives a variation formula for the renormalized volume involving scalar curvature.

Abstract

With respect to any special boundary defining function, a conformally compact asymptotically hyperbolic metric has an asymptotic expansion near its conformal infinity. If this expansion is even to a certain order and satisfies one extra condition, then it is possible to define its renormalized volume and show that it is independent of choices that preserve this evenness structure. We prove that such expansions are preserved under normalized Ricci flow. We also study the variation of curvature functionals in this setting, and as one application, obtain the variation formula $$ \frac{\rm d}{{\rm d}t} {\rm RenV}\big(M^n, g(t)\big) = -\mathop{\vphantom{T}}^R \! \! \! \int_{M^n} (S(g(t))+n(n-1)) {\rm d}V_{g(t)},$$ where $S(g(t))$ is the scalar curvature for the evolving metric $g(t)$, and $\mathop{\vphantom{T}}^R \! \! \! \int (\cdot) {\rm d}V_g$ is Riesz renormalization. This extends our earlier work to a broader class of metrics.

21 pages

Topics & keywords

#ricci flow#asymptotically hyperbolic manifolds#renormalized volume#conformally compact metrics#curvature functionalsRicci flowrenormalized volumeasymptotically hyperboliceven expansionscalar curvatureRiesz renormalization