A Brunn–Minkowski type inequality for Fano manifolds and some uniqueness theorems in Kähler geometry

Abstract

For \(\phi \) a metric on the anticanonical bundle, \(-K_X\), of a Fano manifold \(X\) we consider the volume of \(X\)

$$\begin{aligned} \int _X e^{-\phi }. \end{aligned}$$

In earlier papers we have proved that the logarithm of the volume is concave along geodesics in the space of positively curved metrics on \(-K_X\). Our main result here is that the concavity is strict unless the geodesic comes from the flow of a holomorphic vector field on \(X\), even with very low regularity assumptions on the geodesic. As a consequence we get a simplified proof of the Bando–Mabuchi uniqueness theorem for Kähler–Einstein metrics. A generalization of this theorem to ‘twisted’ Kähler–Einstein metrics and some classes of manifolds that satisfy weaker hypotheses than being Fano is also given. We moreover discuss a generalization of the main result to other bundles than \(-K_X\), and finally use the same method to give a new proof of the theorem of Tian and Zhu on uniqueness of Kähler–Ricci solitons.

Appendix

Here we will prove Proposition 10.1. We suppress the dependence of \(\phi \) on \(t\) and \(s\) in the formulas and use subscripts only to denote differentiation with respect to these variables.

$$\begin{aligned} \frac{d}{ds}\int \dot{\phi _t}(i\partial \bar{\partial }\phi )^n e^{a h^{\phi }}&= \int \ddot{\phi }_{t,s} (i\partial \bar{\partial }\phi )^n e^{a h^{\phi }} \\&\quad +\,n\int \dot{\phi _t}(i\partial \bar{\partial }\dot{\phi }_s)\wedge (i\partial \bar{\partial }\phi )^{n-1} e^{a h^{\phi }}\\&\quad +\,a\int \dot{\phi _t}V(\dot{\phi }_s)\wedge (i\partial \bar{\partial }\phi )^{n} e^{a h^{\phi }}=:I+II+III. \end{aligned}$$

Integrating by parts we get

$$\begin{aligned} II&= - n\int i\partial \dot{\phi _t}\wedge \bar{\partial }\dot{\phi _s}\wedge (i\partial \bar{\partial }\phi )^{n-1} e^{ah^\phi }\\&-\,an\int i\dot{\phi _t}\partial h^{\phi }\wedge \bar{\partial }\dot{\phi _s}\wedge (i\partial \bar{\partial }\phi )^{n-1} e^{ah^\phi }. \end{aligned}$$

Recall that \(i\bar{\partial }h^\phi =V\rfloor i\partial \bar{\partial }\phi \) so that we have \(-i\partial h^\phi =\bar{V}\rfloor i\partial \bar{\partial }\phi .\) Since contraction with a vector field is an antiderivation we get

$$\begin{aligned} 0=\bar{V}\rfloor (\bar{\partial }\dot{\phi _s}\wedge (i\partial \bar{\partial }\phi )^n)=\overline{V(\dot{\phi _s})} (i\partial \bar{\partial }\phi )^n+n\bar{\partial }\dot{\phi _s}\wedge i\partial h^\phi \wedge (i\partial \bar{\partial }\phi )^{n-1}. \end{aligned}$$

Inserting this above we see that

$$\begin{aligned} II=- n\int i\partial \dot{\phi _t}\wedge \bar{\partial }\dot{\phi _s}\wedge (i\partial \bar{\partial }\phi )^{n-1} e^{ah^\phi }-a\int \dot{\phi _t}\overline{V(\dot{\phi _s})}(i\partial \bar{\partial }\phi )^ne^{ah^\phi }. \end{aligned}$$

Hence

$$\begin{aligned} \frac{d}{ds}\int \dot{\phi _t}(i\partial \bar{\partial }\phi )^n e^{a h^{\phi }}&= \int \ddot{\phi }_{t,s} (i\partial \bar{\partial }\phi )^n e^{a h^{\phi }}\\&\quad -\, n\int i\partial \dot{\phi _t}\wedge \bar{\partial }\dot{\phi _s}\wedge (i\partial \bar{\partial }\phi )^{n-1} e^{ah^\phi }\\&\quad +\, 2ia\int \dot{\phi _t}\mathrm{Im\, }V(\dot{\phi }_s)\wedge (i\partial \bar{\partial }\phi )^{n} e^{a h^{\phi }}. \end{aligned}$$

But the left hand side of this equality is real so the last term must be zero (which is also clear since \(\phi \) is invariant under the flow of \(\mathrm{Im\, }V\)). We are then left with the formula in Proposition 10.1.