1 Introduction
During the past few decades, many works arise on the explicit construction of scalar-flat Kähler metrics on noncompact manifolds, usually with certain symmetry conditions. The prototypical example goes back to a seminal work by E. Calabi [Reference Calabi10], who constructed complete Ricci-flat metrics on the canonical bundle of $\mathbb {C}\mathbb {P}^n$ . In complex dimension two, Calabi’s construction produces the Eguchi–Hanson instanton [Reference Eguchi and Hanson17] on the total space of $\mathcal {O}(-2)$ . As a generalization of Eguchi–Hanson, LeBrun [Reference LeBrun25] constructed a family of ALE scalar-flat Kähler metrics in the total space of $\mathcal {O}(-n)$ with $U(2)$ symmetry. Some other works arise to construct families of Ricci-flat Kähler metrics on open manifolds, in some sense, extending the Calabi’s construction, for instance, Stenzel [Reference Stenzel34], Dancer–Wang [Reference Dancer and Wang15], and Wang [Reference Wang38].
There are some essential existence theorems for complete Ricci-flat Kähler metrics on open manifolds. Following Yau’s solution of the Calabi conjecture [Reference Yau40], the analytic approach to the construction of complete Calabi–Yau metrics on noncompact manifolds was initiated by the seminal works of Tian–Yau [Reference Tian and Yau36, Reference Tian and Yau37]. The work by Conlon–Hein [Reference Conlon and Hein13] establishes the existence results for AC Ricci-flat Kähler metrics. Recently, initiated by Li [Reference Li28], many nontrivial Calabi–Yau metrics has been constructed in $\mathbb {C}^n$ with Euclidean volume growth by Conlon–Rochon [Reference Conlon and Rochon14], Székelyhidi [Reference Székelyhidi35], and Apostolov–Cifarelli [Reference Apostolov and Cifarelli3].
For the scalar-flat case, LeBrun [Reference LeBrun26] adapted the Gibbons–Hawking ansatz in hyperbolic model to construct scalar-flat Kähler metrics with $S^1$ symmetry. Joyce [Reference Joyce23] extended LeBrun’s hyperbolic ansatz to toric manifolds and Calderbank–Singer [Reference Calderbank and Singer11] applied Joyce’s construction to toric resolutions of $\mathbb {C}^2/\Gamma $ with cyclic quotient singularities and constructed a family of $T^2$ -invariant ALE scalar-flat Kähler metrics. Based on Donaldson’s reformulation of Joyce construction in [Reference Donaldson16], Abreu–Sena–Dias [Reference Abreu and Sena-Dias1] constructed complete scalar-flat toric Kähler metrics on symplectic toric 4-manifolds which are asymptotic to generalized Taub-NUT metrics.
Lock–Viaclovsky [Reference Lock and Viaclovsky29] constructed scalar-flat Kähler metrics on the minimal resolutions of $\mathbb {C}^2/\Gamma $ , where $\Gamma $ is a finite subgroup of $U(2)$ with no reflections. The existence of ALE scalar-flat Kähler metrics in small deformations of resolutions of $\mathbb {C}^2/\Gamma $ also has been investigated by Honda [Reference Honda19, Reference Honda20], Lock–Viaclovsky [Reference Lock and Viaclovsky29], and Han–Viaclovsky [Reference Han and Viaclovsky18].
In the cases of complex toric surface, the uniqueness of ALE scalar-flat Kähler metrics have been obtained by Sena–Dias [Reference Sena-Dias32], together with work by Wright [Reference Wright39]. However, the general uniqueness of ALE scalar-flat Kähler metric still remains completely open (unlike in the compact case [Reference Berman and Berndtsson5, Reference Chen12], or in the case with cusps [Reference Auvray4] or with conical singularities [Reference Li and Zheng27]). This paper is concerned with a generalization of LeBrun’s existence results to a class of spaces with strong symmetry in all dimensions and proves the uniqueness of scalar-flat Kähler metrics in each Kähler class on these spaces under a symmetry assumption.
A compact homogeneous Kähler manifold is a compact Kähler manifold $(X,\omega )$ on which the identity component of the bi-holomorphic isometry group acts transitively. The classification of this type of spaces has been known for a long time. By [Reference Besse6], every compact, simply connected homogeneous Kähler manifold is isomorphic, in the sense of homogeneous complex manifolds, to an orbit of the adjoint representation of some compact semisimple Lie group endowed with a canonical complex structure. Then, the classification of compact homogeneous Kähler manifolds reduces to classifying the orbit space of adjoint representation. In general, each compact homogeneous Kähler manifold is the product of a flat complex torus and a compact simply connected homogeneous Kähler manifold. In this paper, we are only interested in the compact homogeneous Kähler manifolds without torus part, which we call generalized flag varieties.
Theorem A Let X be a generalized flag variety, and let L be a negative homogeneous line bundle over X with $p: L\rightarrow X$ , the natural projection. Then, all invariant Kähler metrics $\omega $ on L can be written as
where $\omega _X$ is an invariant Kähler form on X and $\varphi (r)\in C^\infty (\mathbb {R}_{\geq 0})$ .
Based on Theorem A, we have identified the G-invariant Kähler metrics in a given Kähler class on L with a class of single variable function. To determine the complete scalar-flat Kähler metrics in a given Kähler class, the method of momentum construction developed in Hwang–Singer [Reference Hwang and Singer22] is applied, which reduces the problem to solving a second-order ODE. In conclusion, we have the following theorem.
Theorem B Let X be a generalized flag variety, and let L be a negative homogeneous line bundle over X. Then, in each Kähler class on L, there exists a unique G-invariant scalar-flat Kähler metric. In particular, this metric is an asymptotically conical Kähler metric.
2 Geometry of compact homogeneous Kähler manifolds
In this section, we recall the geometry of compact homogeneous Kähler manifolds. In Sections 2.1 and 2.2, we discuss the classification of simply connected compact homogeneous Kähler manifolds and holomorphic line bundles over these manifolds. Section 2.3 dedicates to classify all G-invariant Kähler forms on generalized flag varieties.
Here, we introduce some basic notations (see [Reference Knapp24] for more details). Let X be a simply connected compact homogeneous Kähler manifold and G, the universal covering of the compact semisimple Lie group acts on X. At a distinguished point $p \in X$ , let R be the isotropy group of p and S, the identity component of the center of R. $G^{\mathbb {C}}$ denotes the complexification of G. Let T be a fixed maximal torus of G. The corresponding Lie algebra of S, T, R, G are denoted by $\mathfrak {s}$ , $\mathfrak {t}$ , $\mathfrak {r}$ , $\mathfrak {g}$ and $\mathfrak {s}^{\mathbb {C}}$ , $\mathfrak {t}^{\mathbb {C}}$ , $\mathfrak {r}^{\mathbb {C}}$ , $\mathfrak {g}^{\mathbb {C}}$ , the complexification of Lie algebras. We write $\Delta $ to be the root system of $\mathfrak {g}^{\mathbb {C}}$ with respect to $\mathfrak {t}^{\mathbb {C}}$ and $\Delta ^+$ , $\Pi $ , the fixed positive root system and simple root system. For each root $\alpha \in \Delta $ , $\mathfrak {g}_\alpha $ denotes the eigen-space of $\alpha $ . Since G is a compact semisimple Lie, the negative Killing form, denoted by $(\cdot , \cdot )$ , defines a G-invariant inner product in $\mathfrak {g}$ .
2.1 Classification of compact homogeneous Kähler manifolds
According to [Reference Matsushima30], it was proved that the centralizer of S in G is R. So the maximal tori containing S must be contained in R. In the following, we fix a maximal torus T with $S\subset T\subset R$ .
Notice that $\mathfrak {g}^{\mathbb {C}}$ admits a root space decomposition,
We introduce a normalized adapted basis $\{X_\alpha , Y_\alpha \}$ of each pair of root spaces $\mathfrak {g}_\alpha \oplus \mathfrak {g}_{-\alpha }$ , which satisfies the following:
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(a) Let $\mathfrak {g}_\alpha $ and $\mathfrak {g}_{-\alpha }$ denote the complex eigen-spaces corresponding to the roots $\alpha $ and $-\alpha $ . Then
(2.1) $$ \begin{align} X_\alpha-iY_\alpha= E_{\alpha}\in \mathfrak{g}_\alpha\quad\text{and} \quad X_\alpha+iY_\alpha=E_{-\alpha}\in \mathfrak{g}_{-\alpha}. \end{align} $$ -
(b) $X_\alpha $ and $Y_\alpha $ are normalized in the sense that,
(2.2) $$ \begin{align} [X_\alpha,Y_\alpha]=- H_\alpha, \end{align} $$where $H_\alpha $ satisfies $\beta ( H_\alpha )= (\beta ,\alpha )/2i$ for each root $\beta $ . Consider the inner product induced by the negative Killing form. One can easily check that $|X_\alpha |^2=|Y_\alpha |^2=1/2$ . This normalization will be applied in Section 3.1 to calculate the differential of invariant 1-forms.
Then the compact real sub-algebra $\mathfrak {g}$ can be decomposed as follows:
Next, we classify simply connected compact homogeneous Kähler manifolds by the structure of root system. Consider a parabolic subgroup P of $G^{\mathbb {C}}$ . Then P is determined by a subset of the simple root system. Let $(\Delta ^+)' \subset \Delta ^+$ be the subset of positive roots generated by $\Pi '$ . The corresponding Lie algebra $\mathfrak {p}$ can be decomposed as
where $\mathfrak {b}$ is the Lie algebra of the Borel subgroup. The generalized flag variety with data $(G, \Pi , \Pi ')$ is defined to be the complex manifold $X = G^{\mathbb {C}} / P$ .
Assuming that $X = G^{\mathbb {C}} /P$ , we show that X is simply connected compact homogeneous Kähler manifold. Consider the maximal compact subgroup G of $G^{\mathbb {C}}$ . Then G acts transitively on X with stabilizer group $R=G \cap P$ . The Lie algebra of the stabilizer group R is
Then, topologically, $X\cong G/R$ , and its complex structure can also be described as follows. Let
Then $D^+$ is a closed subset of the root system in the sense that for any $\alpha , \ \beta \in D^+ $ , if $\alpha +\beta $ is a root, then $\alpha +\beta \in D^+$ . The tangent space of X at a distinguished point p can be identified with
We also call $\{X_\alpha , Y_\alpha : \alpha \in D^+ \}$ a normalized adapted basis of X. There exists a natural R-invariant almost complex structure J on $T_p X$ given by
Because J is R-invariant, it extends to a G-invariant almost complex structure on the whole tangent bundle $TX$ . The complexified tangent space at p splits into
One can check that J is an integrable almost complex structure because $D^+$ is closed (see [Reference Borel and Hirzebruch7, Section 12]), and the complex manifold $(X,J)$ is G-equivariantly biholomorphic to $G^{\mathbb {C}}/P$ .
Generalized flag varieties are simply connected and the proof of this fact will be given in Remark 2.2. There exist Kähler forms on $(X,J)$ , as discussed in Section 2.3. Hence, each generalized flag variety is a simply connected compact homogeneous Kähler manifold of G.
Conversely, given a simply connected compact homogeneous Kähler manifold X that admits a transitive holomorphic action by a simply connected compact semisimple Lie group G with data $(R, T, S)$ and a point $p \in X$ as above, let $\Delta (\mathfrak {t}, \mathfrak {r})$ denote the root system of $\mathfrak {r}^{\mathbb {C}}$ with respect to $\mathfrak {t}^{\mathbb {C}}$ . This can be viewed as a subset of $\Delta $ . Define
The invariant complex structure J on X determines the set of positive roots $D^+$ as follows. Since the complexified tangent space of X is identified with
the R-invariance of J implies that J preserves each root space. Then $D^+$ is defined to be
The closedness of $D^+$ follows from the integrability of J. In addition, we can choose a simple root system $\Pi '$ in $\Delta (\mathfrak {t},\mathfrak {r})$ . Then $D^+$ and the positive roots, $\Delta ^+(\mathfrak {t}, \mathfrak {r})$ , generated by $\Pi '$ determine a positive root system $\Delta ^+(\mathfrak {t}, \mathfrak {r})$ in $\Delta (\mathfrak {t}, \mathfrak {g})$ , i.e.,
The set $\Pi '$ can be extended to a simple root system, $\Pi $ , of $\Delta (\mathfrak {t}, \mathfrak {g})$ such that $\Pi $ generates the positive roots $\Delta ^+(\mathfrak {t},\mathfrak {g})$ . More details on root systems can be found in [Reference Borel and Hirzebruch7, Sections 13.6 and 13.7]. Based on this discussion, the Lie algebra $\mathfrak {r}$ can be written in terms of the simple root set $\Pi '$ as in (2.5). Thus, X can be identified with the generalized flag variety associated with the data $(G, \Pi , \Pi ')$ .
The notion of a generalized flag variety is actually independent of the choice of a simple root system. By [Reference Adams2, Section 5.13], the different simple root systems are identified by the action of the Weyl group, and then the associated generalized flag varieties are isomorphic via conjugation by an element of G. Hence, without loss of generality, we can fix a simple root system $\Pi $ at the beginning, and then each generalized flag variety of G is classified in terms of a subset of $\Pi $ .
In conclusion, we have proved the following theorem, which should be well-known to experts.
Theorem 2.1 Let X be a compact Kähler manifold. Assume that X is homogeneous under a simply connected compact semisimple Lie group G. Fix a system of simple roots $\Pi $ of $\mathfrak {g}^{\mathbb {C}}$ . Then X is G-equivariantly biholomorphic to the generalized flag variety of type $\Pi '$ for some subset $\Pi '\subset \Pi $ , i.e.,
Remark 2.2 In fact, all homogeneous manifolds discussed in this paper are simply connected. More precisely, let X be a compact Kähler manifold homogeneous under a simply connected semisimple compact Lie group G. Then X is simply connected. This fact follows quickly from the fiber bundle $R \hookrightarrow G \to X$ . Let $X=G/R$ , and let S be the connected center of R. According to the statement $(*)$ , R is the union of all the maximal tori containing S, which implies that R is connected. The fiber bundle structure $R \hookrightarrow G \to X$ induces a long exact sequence of homotopy groups
and this tells us that $\pi _1(X)=0$ .
According to [Reference Borel and Remmert8, Satz I], each compact homogeneous Kähler manifold is the product of a flat complex torus and a simply connected compact homogeneous Kähler manifold. Furthermore, the connected component of the identity of the automorphism group of X is a semisimple Lie group [Reference Borel and Remmert8, Satz 4]. In conclusion, Theorem 2.1 classifies all compact homogeneous Kähler manifolds without torus part.
2.2 Classification of holomorphic line bundles
Consider a holomorphic line bundle L over X, with $\pi : L \rightarrow X$ . The holomorphic line bundle is said to be $G^{\mathbb {C}}$ -homogeneous (or in many articles $G^{\mathbb {C}}$ -linearizable) if there exists a $G^{\mathbb {C}}$ -action on L such that the projection $\pi $ is $G^{\mathbb {C}}$ -equivariant and the action is linear on fibers. In particular, we can construct $G^{\mathbb {C}}$ -homogeneous line bundle as follows.
Given a one-dimensional holomorphic representation $\chi :P\rightarrow \mathbb {C}^*$ , a $G^{\mathbb {C}}$ -equivariant holomorphic line bundle $L_\chi $ over $X = G^{\mathbb {C}}/P$ can be constructed as follows:
where $(gh, v)\sim (g,\chi (h)v)$ for all $g\in G^{\mathbb {C}}$ , $h\in P$ , $v\in \mathbb {C}$ . This admits a natural $G^{\mathbb {C}}$ -action given by
for all $g\in G^{\mathbb {C}}$ , $l\in G^{\mathbb {C}}$ , $v \in \mathbb {C}$ . Conversely, given a $G^{\mathbb {C}}$ -equivariant holomorphic line bundle L over X, the stabilizer group P at the distinguished point $p\in X$ acts on the fiber $L_p$ , inducing a holomorphic character $\chi : P \rightarrow \mathbb {C}^*$ such that $L \cong L_\chi $ . In conclusion, there is a one-to-one correspondence between the $G^{\mathbb {C}}$ -homogeneous line bundles over X and the characters of P.
Let L be an arbitrary holomorphic line bundle over X. We claim that L is a $G^{\mathbb {C}}$ -homogeneous line bundle. To prove this claim, we need to borrow some results from algebraic geometry. Referring to [Reference Humphreys21, Section 21.3], X is a projective variety. According to a well-known result from GAGA [Reference Serre33], holomorphic line bundles over a projective variety are algebraic; in other words, the line bundle L is algebraic over X. Moreover, since $G^{\mathbb {C}}$ is a simply connected semisimple Lie group, by [Reference Popov31, Proposition 1], the Picard group of $G^{\mathbb {C}}$ is trivial. According to the key fact that $\operatorname {Pic} G^{\mathbb {C}} =0 $ , we can construct a character $\chi : P \rightarrow \mathbb {C}^*$ such that $L \cong L_\chi $ (see [Reference Popov31, Theorem 4 or Section 5] for details). Thus, we have the following proposition:
Proposition 2.3 All holomorphic line bundles over X are $G^{\mathbb {C}}$ -homogeneous.
Fixing a simple root system $\Pi $ of G, let $X\cong G^{\mathbb {C}}/ P$ , where the parabolic subgroup P is determined by a subset of simple roots $\Pi '\subset \Pi $ as in (2.4). Let $\Pi =\{\alpha _1,\ldots , \alpha _n\}$ be ordered in such a way that $\alpha _i\in \Pi '$ if and only if $i=k+1,\ldots , n$ . Let $\{\omega _1,\ldots , \omega _n\}$ be the set of fundamental weights corresponding to $\Pi $ , which are defined by
Here, the inner product is the bilinear form induced by the Killing form of $\mathfrak {g}$ . The lattice generated by $\{\omega _1,\ldots ,\omega _n\}$ , i.e., all vectors of the form $\sum _{n_i\in \mathbb {Z}} n_i \omega _i$ , is called the lattice of algebraically integral weights. Since G is a simply connected semisimple Lie group, the analytically integral weights coincide with the algebraically integral weights (see [Reference Knapp24, Chapter IV.7]). Thus, each algebraically integral weight induces a character of the maximal torus T. Recall that $\mathfrak {s},\mathfrak {s}^*$ denote the Lie algebra of S and its dual space, respectively. More precisely,
Then $(\mathfrak {s}^{\mathbb {C}})^*=\mathbb {C} \langle \omega _1,\ldots ,\omega _k\rangle $ and the intersection of the weight lattice with $(\mathfrak {s}^{\mathbb {C}})^*$ is $\mathbb {Z}\langle \omega _1,\ldots , \omega _k\rangle $ . We call the elements of this sublattice integral weights on X. Given such an element $\lambda $ , there exists an associated character $\chi ^\lambda : S^{\mathbb {C}}\rightarrow \mathbb {C}^*$ defined by
for all $v \in \mathfrak {s}^{\mathbb {C}} \subset \mathfrak {t}^{\mathbb {C}}$ . The character $\chi ^\lambda $ can be extended to P in the following way. The Lie subalgebra $\mathfrak {p}$ can be decomposed as follows:
where $ \mathfrak {p}_1$ is the solvable part of $\mathfrak {p}$ , $\mathfrak {n} $ is the nilpotent part of $\mathfrak {p}_1$ , and $\mathfrak {p}_2$ is the semisimple part of $\mathfrak {p}$ . Each integral weight $\lambda $ on X can be extended to a complex Lie algebra homomorphism $\sigma :\mathfrak {p} \rightarrow \mathbb {C}$ by defining the extension to be $0$ on both $\mathfrak {n}$ and $\mathfrak {p}_2$ . Then the corresponding holomorphic character $\chi ^\sigma $ extends $\chi ^\lambda $ from $S^{\mathbb {C}}$ to P. By abuse of notation, we will denote this extension by $\chi ^\lambda $ . The following proposition shows that all characters of P arise by extension in this way.
Proposition 2.4 For all holomorphic characters $\chi : P\rightarrow \mathbb {C}^*$ , there exists an integral weight $\lambda $ on X such that $\chi =\chi ^\lambda $ .
Proof The character $\chi : P\rightarrow \mathbb {C}^*$ induces a Lie algebra homomorphism $\sigma : \mathfrak {p}\rightarrow \mathbb {C}$ . It suffices to prove that $\sigma $ is trivial if restricted to $\mathfrak {n}$ and $\mathfrak {p}_2$ . Notice that $\mathfrak {p}_1$ is a solvable Lie algebra and $\mathfrak {n}=[\mathfrak {p}_1,\mathfrak {p}_1]$ . The restriction of $\sigma $ to $\mathfrak {n}$ must be trivial as $\mathbb {C}$ is an abelian Lie algebra. Since $\mathfrak {p}_2$ is a semisimple Lie algebra, for each root $\alpha \in D^+$ , there exist $X_{\alpha }\in \mathfrak {g}_\alpha $ , $X_{-\alpha }\in \mathfrak {g}_{-\alpha }$ and $H_{\alpha }=[X_\alpha ,X_{-\alpha }]$ such that
By the representation theory of $\mathfrak {s}\mathfrak {l}(2,\mathbb {C})$ , the only possible one-dimensional representation of $\mathfrak {l}_\alpha $ is trivial. Since the restriction of $\sigma $ to each $\mathfrak {l}_\alpha $ is trivial, we conclude that $\sigma |_{\mathfrak {p}_2}=0$ .
Summarizing, we have now proved that every integral weight $\lambda \in \mathbb {Z}\langle \omega _1,\ldots , \omega _k \rangle $ induces a character, $\chi ^\lambda : P\rightarrow \mathbb {C}^*$ , hence a homogeneous line bundle $L_\lambda $ . Conversely, every holomorphic line bundle L is of the form $L\cong L_\lambda $ for some $\lambda \in \mathbb {Z}\langle \omega _1, \ldots , \omega _k \rangle $ . Recall that an integral weight $\lambda $ on X is called dominant if $\lambda =\sum _{i=1}^kn_i\omega _i$ with $n_i>0$ . By the Highest Weight Theorem, for each dominant integral weight $\lambda $ , there exists a unique finite-dimensional irreducible complex representation $V(\lambda )$ of G with highest weight $\lambda $ . The Bott–Borel–Weil Theorem [Reference Bott9, Section 7] states that the space of global sections of $L_\lambda $ is isomorphic to $V(\lambda )$ as a G-module. Also by the Bott–Borel–Weil Theorem, the global sections of $L_\lambda $ induce an embedding $X\hookrightarrow \mathbb {P}(V(\lambda )^*)$ , so $L_\lambda $ is very ample. In conclusion, we have the following.
Theorem 2.5 The Picard group of the compact homogeneous Kähler manifold X can be identified with the sublattice $\mathbb {Z}\langle \omega _1,\ldots ,\omega _k\rangle $ of the lattice of integral weights. Under this identification, ample line bundles correspond to dominant integral weights, and are automatically very ample.
Proof Given the previous discussion, we only need to prove that if $L_\lambda $ is ample, then the weight $\lambda $ is dominant. We will calculate the curvature form of $L_\lambda $ in (3.9). The curvature form is positive if and only if $(\lambda , \alpha )>0$ for all $\alpha \in D^+$ , which implies that $\lambda $ is dominant.
2.3 Invariant closed (1,1)-forms on X
In this section, we classify the G-invariant closed $(1,1)$ -forms on X, which is needed for the proof of Theorem B.
Throughout this section, let X be a compact homogeneous Kähler manifold with respect to $(G,R)$ . Fixing a distinguished point $p\in X$ , let $\{X_\alpha , Y_\alpha : \alpha \in D^+\}$ be a normal adapted basis of $T_p X$ as defined in (2.1) and (2.2). Then, we write $\{\eta _\alpha , \xi _\alpha : \alpha \in D^+ \}$ for the dual basis of $T_p^* X$ .
The results that we will discuss here mainly come from [Reference Besse6, Chapter 8]. A slight difference is that we rewrite the results in more explicit way. Recall that tangent vectors at p can be identified with infinitesimal transformation at p by elements in $\mathfrak {g}$ . If $A\in \mathfrak {g}$ , we define $V_A$ as a vector field on X by
We call $V_A$ the fundamental vector field related to A. Then, by quick calculation, the Lie bracket of two fundamental vector fields is also fundamental as
The reason we introduce fundamental vector fields is to test invariant 2-forms on X. Recall that the negative Killing form defines a G-invariant metric $(\cdot ,\cdot )$ on $\mathfrak {g}$ . Fixing an element $S\in \mathfrak {s}$ , we can define a 2-form, $\omega _S(V_A, V_B) = (S, [A,B])$ . According to the standard calculation (see [Reference Besse6, Proposition 8.66]), $\omega _S$ is a G-invariant, closed, real $(1,1)$ -form. It is observed that the only nonvanishing terms are
The observation (2.13) indicates that we can write down $\omega _S$ explicitly in terms of the covector basis $\{\eta _\alpha ,\xi _\alpha : \alpha \in D^+\}$ at $p\in X$ . Precisely,
where $C_S$ can be viewed as a linear function of $\mathfrak {s}^*$ (generated by elements in $D^+$ ).
Given a G-invariant closed real $(1,1)$ -form, $\omega $ , in the following, we prove that $\omega $ can be written as in (2.14) related to some S. Since $\omega $ is G-invariant, for each $A,B,N\in \mathfrak {g}$ ,
In particular, by taking N to be an element in $\mathfrak {t}$ and $A,B$ to be elements of $\{X_\alpha , Y_\alpha , \alpha \in D^+\}$ , noting that $V_N(\omega (V_A, V_B)) = 0$ , we have:
-
• For two different roots in $D^+$ , $\alpha , \beta $ , $\omega (X_\alpha , X_\beta )=\omega (X_\alpha , Y_\beta )=\omega (Y_\alpha ,Y_\beta )=0.$
-
• The only nonvanishing case are $\displaystyle \omega (X_\alpha ,Y_\alpha )=C_\alpha , \alpha \in D^+$ .
It suffices to show that $C_\alpha $ , a function defined in $D^+$ , can extend linearly to $\mathfrak {s}^*$ . Since $2$ -form $\omega $ and inner product in $\mathfrak {g}$ can be extended linearly to complex field, consider the following complex vectors:
where $\alpha , \beta , \alpha +\beta \in D^+$ and $X_{\alpha ,\beta ,\alpha +\beta }$ , $Y_{\alpha ,\beta ,\alpha +\beta }$ are taking from the normal adapted basis as in (2.1) and (2.2). Viewing U, V, W as elements in $\mathfrak {g}\otimes \mathbb {C}$ , the G-invariant inner product satisfies
Therefore, it is easy to check $U,V,W$ satisfies the following:
By closedness and G-invariance of $\omega $ , we have
Inserting (2.15) into (2.16), we have
hence, $C_{\alpha +\beta }=C_{\alpha }+C_\beta \ (*)$ . Noticing that $C_{\bullet }$ defines a function on $D^+$ , the condition $(*)$ implies that $C_{\bullet }$ can be extended to a linear function on $\mathfrak {s}^*$ as $D^+$ generates $\mathfrak {s}^*$ . In other words, there exists an element $S\in \mathfrak {s}$ such that
In conclusion, we have the following proposition.
Proposition 2.6 For any $S\in \mathfrak {s}$ , the 2-form $\omega _S$ given by (2.14) is a G-invariant closed real $(1,1)$ -form. Conversely, any G-invariant closed real $(1,1)$ -form, $\omega $ , can be related to a unique $S\in \mathfrak {s}$ , i.e., $\omega =\omega _S$ . The form $\omega _S$ is positive if and only if $C_S(\alpha ) = \frac {i}{2} \alpha (S)$ is positive for all $\alpha \in D^+$ .
Proposition 2.6 implies a bijection from $\mathfrak {s}$ to the space of G-invariant closed real $(1,1)$ -forms on X, $S\rightarrow \omega _S$ . There is a special element of the G-invariant closed real $(1,1)$ -forms, Kähler–Einstein form, and the related element in $\mathfrak {s}$ is given by ${S_{KE}=2\sum _{\alpha \in D^+} H_{\alpha }.}$ So we can write $\omega _{KE}$ explicitly at the distinguished point $p\in X$ with respect to the normal adapted basis. Indeed, set $\delta $ be the sum of all positive roots in $D^+$ , then
3 Invariant $dd^C$ -lemmas on homogeneous line bundles
This section is dedicated to the proof of Theorem A. Section 3.1 discusses invariant $1$ -forms on the unit circle bundle, M, of a homogeneous line bundle L over a compact homogeneous Kähler manifold X. Section 3.2 calculates the differentials of the invariant 1-forms given in Section 3.1. Assuming that L is negative, Section 3.3 proves an invariant $dd^C$ -lemma, and we also show that this $dd^C$ -lemma can be false if L is not negative. Finally, Section 3.4 combines these results to prove Theorem A.
3.1 Invariant $1$ -forms on M
Let X be a homogeneous compact Kähler manifold as before, and $L=L_\lambda $ , a homogeneous line bundle over X corresponding an integral weight $\lambda $ . Given the data $(X,L)$ , in this subsection, we will determine all left-invariant 1-forms on the unit circle bundle M of X.
Recall the G-action on L defined by restricting the $G^{\mathbb {C}}$ -action of (2.10) to ${G \subset G^{\mathbb {C}}}$ . For each homogeneous line bundle L, there is a natural G-invariant Hermitian metric h induced by the standard Hermitian metric in $\mathbb {C}$ . In particular, according to construction of homogeneous line bundle in (2.9), let $q_0= \overline {(g,z)} \in L_\lambda $ for $(g,z)\in G^{\mathbb {C}} \times \mathbb {C}$ , then $h(q_0,q_0)=|z|^2$ . The Hermitian metric h induces a radian function r on L. Then, G acts transitively on each level set of r, an $S^1$ bundle of X, denoted as $M(r)$ . Away from zero level set, there is a canonical invariant vector field, $\partial /\partial r$ on L pointing in radius direction. We shall find the set of all invariant vector fields on each level set $M(r)$ . Notice that, in general, left-invariant vector fields on G are not well-defined over $M(r)$ , as the left action by the stabilizer group on the tangent space at one point can be nontrivial. Let $M=M(1)$ and let $\mathcal {T}_M$ be the space of all global G-invariant vector fields over M. $\mathcal {T}_M$ contains at least one element, $X_0=J(\partial /\partial r)$ , generating a circle action on each fiber. The other elements of $\mathcal {T}_M$ strongly depend on the base manifold X and the integral weight $\lambda $ . According to (2.7), the tangent space at a distinguished point $p\in X$ can be identified with a subspace of $\mathfrak {g}$ . Then, we can choose a normal adapted basis $\{X_\alpha ,Y_\alpha \}_{\alpha \in D^+}$ as in (2.1) and (2.2).
Based on the choice of $\{H_\alpha , X_\alpha , Y_\alpha \}$ as in (2.1) and (2.2), one can easily check the following Lie algebra structure:
Let q be a distinguished point in M with $\pi (q) =p$ , then the tangent space at q can be identified with $\mathbb {R}\langle X_\alpha , Y_\alpha , \alpha \in D^+ \rangle \oplus \mathbb {R} X_0$ in the following sense. Consider the G-equivariant bundle projections,
with $\tilde {\pi }(e)=q\in M$ . At the distinguished point $q\in M$ with $\pi (q)=p\in X$ , assume that the stabilizer group at $p\in X$ is R and the stabilizer group at $q\in M$ is $R_0$ . By G-action on L, $g\in R_0$ if and only if,
which implies that $R_0= \ker \chi ^\lambda : R\rightarrow S^1 \subset \mathbb {C}^*$ These projections induce the mapping on tangent spaces $\tilde {\pi }_*:\mathfrak {g}\rightarrow T_qM$ by
Similarly, we can define the mapping $\pi _*:\mathfrak {g}\rightarrow T_p X$ . By abusing notation, we write $X_\alpha , Y_\alpha $ instead of $\tilde {\pi }_*(X_\alpha )$ , $\tilde {\pi }_*(Y_\alpha )$ and $\pi _*(X_\alpha ),\ \pi _*(Y_\alpha )$ as $X_\alpha $ , $Y_\alpha $ . Notice that the left-invariant vector fields on G can be identified with $\mathfrak {g}$ . To determine the space of invariant vector fields, $\mathcal {T}_M$ , on $M_1$ , we observe that for any $R_0$ -invariant vector $v\in T_q M$ and $g_1(q)=g_2(q)$ , then $g_1=g_2 r$ with $r\in R_0$ and
So each $R_0$ -invariant vector of $T_q M$ determines a left-invariant vector fields on M. There is an one-to-one correspondence between $\mathcal {T}_M$ and the $R_0$ -invariant space of $T_q M$ . In particular, in the case that $X=G/T$ with T a maximal torus of G, we have the following proposition.
Proposition 3.1 Let X be a compact Kähler manifold homogeneous under G with stabilizer group R, and let $\Delta $ be the root system of $(\mathfrak {t}, \mathfrak {g})$ . $D^+$ is defined as in (2.6). Let M be the unit level of homogeneous line bundle determined by an integral weight $\lambda \ne 0$ . At a distinguished point $q\in M$ , the tangent space $T_q M$ is generated by $\{X_\alpha ,Y_\alpha \}_{\alpha \in D^+}$ and $X_0$ . Then, there are the following two possibilities for the space of the left-invariant vector fields on M:
-
(a) $\mathcal {T}_M \cong \mathbb {R} \langle X_0\rangle .$
-
(b) $\mathcal {T}_M \cong \mathbb {R} \langle X_0, X_\alpha , Y_\alpha \rangle $ , for some $\alpha \in D^+.$
The case (b) happens if and only if $\lambda $ is proportional to $\alpha $ and $\alpha +\beta $ , $\alpha -\beta $ are not in $\Delta $ , for any nontrivial $\beta \in \Delta (\mathfrak {t}, \mathfrak {r})$ . In particular, if the stabilizer group is a maximal torus, then the case (b) happens if and only if $\lambda $ is proportional to $\alpha $ .
Proof of Proposition 3.1
Let $R_0$ be the stabilizer group at $q\in M$ . Notice that $R_0$ is the kernel of character $\chi ^\lambda : R\rightarrow S^1\subset \mathbb {C}$ related to the weight $\lambda $ . Let $ V\in T_q M$ be an invariant vector. According to decomposition (2.7) of $T_q M$ , the vector V can be written as
Notice that $R_0$ preserves each $\mathbb {R}\langle X_\alpha , Y_\alpha \rangle $ . If a vector $V_\alpha = aX_\alpha +bY_\alpha \in E_{\pm \alpha }$ is invariant under $R_0$ action, then, since J is $R_0$ invariant, which means that $J(aX_\alpha +bY_\alpha )=aY_\alpha -bX_\alpha $ is also $R_0$ invariant. Therefore, all vectors in the space generated by $\langle aX_\alpha +bY_\alpha ,-b X_{\alpha }+a Y_\alpha \rangle =\langle X_\alpha , Y_\alpha \rangle = \mathbb {R}\langle X_\alpha , Y_\alpha \rangle $ are $R_0$ invariant. So we only need to determine the set of all $\alpha \in \Delta ^+$ such that $X_\alpha $ , $Y_\alpha $ are invariant under $ R_0 = \ker \chi ^\lambda $ .
Let $\mathfrak {r}_0=\ker \lambda $ , it’s easy to see that $\mathfrak {r}_0$ is the Lie algebra of the stabilizer group $R_0$ . Let $T_0= R_0 \cap T$ associated with Lie algebra $\mathfrak {t}_{0}=\mathfrak {r}_0\cap \mathfrak {t}$ . Since $X_\alpha $ , $Y_\alpha $ is $T_0$ invariant,
Noting that
Hence, we have $\ker \alpha = \mathfrak {t}^0 = \ker \lambda |_{\mathfrak {t}}$ , hence $\lambda $ is proportional to $\alpha $ .
Let $Z \in \mathfrak {r}_0$ , then $X_\alpha ,Y_\alpha $ are $R_0$ invariant if and only if
Notice that $\mathfrak {r}_0 = \mathfrak {t}_0 \oplus \sum _{\beta \in \Delta ^+(\mathfrak {t},\mathfrak {r})}\mathbb {R}\langle X_\beta , Y_\beta \rangle $ , where $\mathfrak {t}_0$ is kernel of $\lambda $ restricted in $\mathfrak {t}$ . Then, $X_\alpha $ and $Y_\alpha $ is $R_0$ -invariant is equivalent to (3.2) and
According to [Reference Knapp24, Theorem 6.6] and the definition of $\tilde {\pi }_*$ , $(**)$ is equivalent to $\alpha + \beta ,\ \alpha -\beta \notin D^+ \cup (-D^+)$ . Indeed, $\alpha +\beta $ and $\alpha -\beta $ are not roots. Assume that
then, $\alpha =\gamma - \beta \in \Delta (\mathfrak {t},\mathfrak {r})$ . But $\alpha \in D^+$ , which leads to a contradiction.
Example 3.2 Let $X=SU(3)/T^{2} $ . Recall the basic notions of semisimple Lie group $SU(3)$ . The Lie algebra $\mathfrak {su}(3)$ is the set of trace zero skew-Hermitian matrices of order $3$ . A Cartan sub-algebra $\mathfrak {t}$ is the Lie algebra of diagonal matrices in $\mathfrak {su}(3)$ . The set of positive roots with respect to $\mathfrak {t}$ consists of three elements $\{\alpha ,\beta ,\gamma \}$ , and the normal adapted basis is given by $X_{\alpha ,\beta ,\gamma },\ Y_{\alpha ,\beta ,\gamma }$ .
Consider a distinguished point $q\in M$ with tangent space generated by $\{X_0,\ X_{\alpha ,\beta ,\gamma },\ Y_{\alpha ,\beta ,\gamma }\}$ . Now, we only focus on the subspace $V\subset T_q M$ generated by $\{X_{\alpha ,\beta , \gamma }, Y_{\alpha , \beta , \gamma }\}$ . To simplify the notation in calculation, we introduce a complex coordinate system in V; precisely, $z_{\alpha }=X_\alpha +i Y_{\alpha }$ . Let $\sigma _i$ denote the ith element of diagonal matrices. Then, $\alpha ,\beta ,\gamma $ can be expressed as, $ \alpha =\sigma _1- \sigma _2 ,\quad \beta =\sigma _1- \sigma _3,\quad \gamma =\sigma _2-\sigma _3. $ Hence, let $\{\alpha ,\gamma \}$ be the simple root system of $SU(3)$ and $\beta =\alpha +\gamma $ . The fundamental weights are given as follows:
Let $\mathcal {O}(p,q)$ denote the line bundle corresponding to the integral weight $\lambda =p\omega _1+q\omega _2$ . In the case of $(p,q)\ne 0$ . Noting that kernel of $\lambda = p\omega _1+ q\omega _2$ is $\mathbb {R}\langle q t_1 - (p+q) t_2\rangle $ . Then, the $S^1$ action is given by $T_\theta ^{p,q}=\operatorname {diag}(e^{iq \theta }, e^{-i(p+q)\theta },e^{ip\theta })$ and if we represent the action on complex coordinate system $(z_\alpha , z_\beta , z_\gamma )$ , we have
In conclusion, we have the following cases:
Notice that
The integral weights in the above table, $-2n\omega _1+ n\omega _2$ , $n\omega _1 + n\omega _2$ , $-n\omega _1 +2n \omega _2$ are proportional to $\alpha ,\beta , \gamma $ , respectively, in agreement with Proposition 3.1.
The left-invariant $1$ -forms on M can be viewed as the dual space of left-invariant vector fields. More precisely, if we apply the previous notion of adapted basis at $T_q M$ , given by $\{X_0, X_\alpha , Y_\alpha; \alpha \in D^+\}$ , we write the dual basis of $T^*_qM$ as $\{\eta _0,\eta _\alpha , \xi _\alpha ;\alpha \in D^+\}.$ According to Proposition 3.1, the space of left-invariant vector fields is in one-to-one correspondence with the space generated by $\{X_0\}$ or $\{X_0, X_\alpha ,Y_\alpha \}$ for some $\alpha \in D^+$ . Consider the subset, $\{\eta _0\}$ or $\{\eta _0,\eta _\alpha ,\xi _\alpha \}$ of the dual basis, whose elements are $R_0$ invariant. Therefore, $\{\eta _0\}$ or $\{\eta _0,\eta _\alpha ,\xi _\alpha \}$ generates the space of G-invariant $1$ -forms over M.
3.2 The differentials of left-invariant 1-forms on M
According to Proposition 3.1, the left-invariant 1-forms are generated by $\{\eta _0 \}$ or $\{\eta _0, \xi _\alpha , \eta _\alpha \}$ . We only consider the second case in this subsection.
Let M be an $S^1$ bundle associated with line bundle L. Notice that there is a natural projection $\tilde {\pi }: G\rightarrow M$ . If we write $\Omega _1$ , $\Omega _2$ as the space of smooth $1$ -forms and $2$ -forms, respectively, then we have the following commutative graph:
Since the left-invariant vector fields are globally generated in G, with a natural basis corresponding to $\{H_\alpha ,X_\beta ,Y_\beta : \alpha \in \Pi ,\beta \in \Delta \}$ and its dual basis $\{h_\alpha ,\eta _\beta ,\xi _\beta :\alpha \in \Pi ,\beta \in \Delta \}$ , then the pull back of $\eta _\alpha $ , $\xi _\alpha $ in $\Omega _1(M)$ under $\tilde {\pi }$ are exactly $\eta _\alpha $ , $\xi _\alpha $ in $\Omega _1(G)$ . And the pull-back of $\eta _0$ is a certain combination of $h_\alpha $ determined by weight $\lambda $ . To calculate the differentials of left-invariant 1-forms, the technique is to apply the Maurer–Cartan equations on G with respect to the natural basis, Since Maurer–Cartan equations gives us the derivative of left-invariant $1$ -form on G, combining the commutative graph (3.3), we have the derivative of left-invariant $1$ -form on M.
Proposition 3.3 Let X be the homogeneous space and M, the $S^1$ bundle of X associated with $\lambda $ . Assuming that, at the distinguished point $q\in M$ , the space of left-invariant $1$ -forms can be identified with the spaces generated by $\{\eta _0,\eta _\alpha ,\xi _\alpha \}$ , $\alpha \in D^+$ . In this case, $\lambda $ is proportional to $\alpha $ , assuming that $\alpha =-l\lambda $ , then the derivative are given by
where the coefficients $C^\alpha _{\beta ,-\gamma }$ are the coefficients from Maurer–Cartan equation. Let $E_\alpha $ , $E_\beta $ , $E_{-\gamma }$ be the root vector of $\alpha $ , $\beta $ , $-\gamma $ satisfying (2.1), then
Proof Let $\{\omega _1, \dots , \omega _k\}$ be fundamental integral weights on X and $\lambda =\sum _{i}n_i\omega _i$ . By the definition of fundamental weights and our setting of $H_{\alpha _i}$ , we can evaluate $H_{\alpha _i}$ under $\lambda $ :
By the definition of $L_\lambda $ , at distinguished point $q\in M$ with $\tilde {\pi }(e)=q$ , we have
For each i,
Since the previous calculation shows that $\omega _i(H_{\alpha _j})=-i|\alpha _j|^2\delta _{ij}/4$ , then the pullback of $\eta _0$ can be represented by $\tilde {\pi }^*\eta _0=-i\lambda $ . To get the formula (3.4), notice that
To get the formulas (3.5) and (3.6), if we pull back both sides of formulas by $\tilde {\pi }$ ,
Since $\tilde {\pi }^*$ is injective, $d\eta _\alpha $ admits the term $\displaystyle \frac {2(\alpha ,\alpha _i)}{n_i|\alpha _i|^2} \eta _0\wedge \xi _\alpha $ . We can show that the coefficient is independent of the index i and related to the factor l. Notice that $\lambda $ is proportional to $\alpha $ , $\alpha =-l\lambda $ , then
To compute the remaining cross terms of $d\eta _\alpha $ and $d\xi _\alpha $ , we shall understand the structure of Lie algebra. Notice that $d\eta _\alpha $ has a nonvanishing 2-form related with root $\beta ,\ \gamma $ only if (1) $\alpha =\beta +\gamma $ or (2) $\alpha =\beta -\gamma $ . Both in the case (1) and (2), we argue that $\beta ,\gamma \in D^+$ . For instance, in the case (1), assume that $\gamma \in \Delta (\mathfrak {t},\mathfrak {r})^+$ , then we have $\beta = \alpha -\gamma $ is a root, which contradicts the condition in Proposition 3.1.
In the case (1), notice that $\displaystyle [E_\beta , E\gamma ]= C^\alpha _{\beta , \gamma } E_\alpha $ and $\displaystyle [E_\beta , \overline {E_\gamma }]$ has no $E_\alpha $ terms. Combining with the relation (2.1), we have
The above equation implies that
Hence, $d\eta _\alpha $ has the term $(C^\alpha _{\beta ,\gamma }/2)(-\eta _\beta \wedge \eta _\gamma + \xi _\beta \wedge \xi _\gamma )$ . Likewise, we can find the formulas for $d\eta _\alpha $ and $d\xi _\alpha $ as (3.5) and (3.6) and we completes the proof.
Fixing a line bundle related to a weight $\lambda $ , the Chern class of $L_\lambda $ can be represented by the form $-i \partial \overline {\partial } \log r^2$ , where r is the radius function induced by some Hermitian metric on $L_\lambda $ . Then we have
Indeed, the 1-form $ \displaystyle -Jdr/r$ is induced by circle action along each fiber and more details will be discussed in the next section. Referring to Proposition 3.3, the curvature form can be represented as
Comparing with (2.17), the Kähler–Einstein metric is the curvature form associated with the anti-canonical bundle, $L_{\delta }$ .
3.3 Invariant $dd^c$ -lemma on $L_\lambda $
Consider the data $(X,L_\lambda )$ as in the previous section. According to Proposition 3.1, the space of left-invariant vector fields on M have two different cases (a) and (b). Suppose that $\lambda $ satisfies one of the following conditions:
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• The space of left-invariant vector fields on M satisfies case (a) in Proposition 3.1.
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• The space of left-invariant vector fields on M satisfies case (b) in Proposition 3.1. And $\lambda $ is proportional to some positive root $\alpha $ with $\lambda = -l \alpha $ , $l>0$ .
Then, we have the following invariant $dd^c$ lemma.
Proposition 3.4 Let $(X,L_\lambda )$ satisfy the conditions above. If $\omega $ is an G-invariant closed real $(1,1)$ -form on L, $[\omega ]=0$ , then there exists a G-invariant Kähler potential $\Phi \in \mathcal {C}^\infty (L_\lambda )$ such that
Proof Since $\omega $ is exact, there exists an 1-form $\theta $ such that $d\theta =\omega $ . Moreover, $\theta $ can choose to be G invariant. Notice that $\omega = d (g^* \theta )$ , then, by taking integral over G, we obtain a G-invariant 1-form $\theta $ with $\omega =d \theta $ .
The main idea of proof is to represent $d\theta $ and $\partial \overline {\partial }\phi $ with respect to G-invariant coframe, then we can reduce the proof of Proposition 3.4 to solving a system of ODE.
Let $L_\lambda $ be the line bundle such that the space of left-invariant vector fields on M satisfies case (b). Suppose that $\lambda $ is proportional to $\alpha $ . The basis of left-invariant $1$ -form on level set M is $\{\eta _0,\eta _\alpha ,\xi _\alpha \}$ . Then, we can extend these invariant $1$ -forms in radian direction by rescaling $1/r$ on each level $M(r)$ . Precisely, there is a natural projection $p: L^\times \rightarrow M$ . By identifying $L^\times \cong G\times _{\lambda }\mathbb {C}^\times $ , the projection can be written explicitly,
Thus, $p^*$ extends $\{\eta _0, \eta _\alpha , \xi _\alpha \}$ to $L^\times $ . By abusing the notion, we write $\{\eta _0, \eta _\alpha , \xi _\alpha \}$ as the extended vector fields over $L^{\times }$ . Also let $\mu = dr/r$ , hence $\{\mu ,\eta _0,\eta _\alpha ,\xi _\alpha \}$ forms a basis of invariant $1$ -forms over $L^\times $ . Then the invariant $1$ -form $\theta $ can be represented as
Applying Proposition 3.3, we can take derivative of $\theta $ in (3.11),
Let J be complex structure. Note that $d\theta $ is real $(1,1)$ -form if and only if $Jd\theta =d\theta $ . Notice that $J\eta _0=\mu $ , $J\xi _\alpha =\eta _\alpha $ , then
Then, $Jd\theta =d\theta $ implies the following ODE:
and the terms of line (3.15) are vanishing. To ensure, the (3.15) vanishes
Indeed, referring to (see [Reference Knapp24], Theorem 6.6), if $\alpha =\beta +\gamma $ , for some $\alpha ,\beta ,\gamma \in \Delta $ , then the corresponding constant $C^\alpha _{\beta ,\gamma }\ne 0$ . Assuming that there exist positive roots, $\beta $ and $\gamma $ , satisfying $\alpha =\beta +\gamma $ , by (3.17), we have $\varphi _\alpha =\phi _\varphi =0$ , which automatically satisfies (3.16); hence, if $d\theta $ is a real $(1,1)$ -form with some structure constants $C^\alpha _{\beta ,\gamma }$ nonvanishing, then $d\theta $ can be written as
When it comes to the cases that the corresponding weight $\lambda $ is proportional to a simple root $\alpha $ , i.e., $\alpha $ cannot be written as the sum of two positive roots, $d\theta $ should satisfy the equation (3.16) and its solution is given by $\varphi =C/r^l$ with C an arbitrary constant. In the sequel, it suffices to show that the constant C in the expression of solution $\varphi $ should equal zero. To prove this, we need to apply the condition that the form, $d\theta $ , is well-defined across the zero level of line bundle. Firstly, we take a reference metric $\omega _0$ near the zero level of line bundle L. Let h be the canonical invariant Hermitian metric defined as before and r be the radial function related to h. Also, given a bundle coordinate u, we have
It is easy to see that $\omega _\epsilon $ is positive around zero level. To simplify calculation, let $\epsilon $ tends to $0$ , then we obtain a semi-positive form $\omega _0=\pi ^* \omega _{KE}$ . Consider the following integration:
where the K is a compact neighborhood of zero level, which is defined as $K=\{x\in L, r(x) \leq \delta \}$ . In the sequel, we write 3.12, 3.13, and 3.14 as $\Theta _1$ , $\Theta _2$ , $\Theta _3$ . Noticing that all crossing terms $\Theta _i\wedge \Theta _j\wedge \omega _0^{n-1}=0$ , ( $i\ne j$ ), and $\Theta _3\wedge \Theta _3\wedge \omega _0^{n-1}=0$ . Only two nonvanishing terms of the integration (3.18) are the following:
Inserting the solution of ODE (3.16),
then we can compute the two terms in (3.19) separately,
and assume $\lambda $ is proportional to a positive root by a negative constant,
Hence, $\displaystyle \int _K d\theta \wedge d\theta \wedge \omega _0^{n-1}=-\infty $ , which leads to a contradiction. We obtain that $\varphi _\alpha =\phi _\alpha =0$ . According to the discussion of two cases, we have $\varphi _\alpha =\phi _{\alpha }=0$ and $d\theta $ can be represented as
Take a function $\Phi (r)$ such that $\Phi '(r)=\varphi _0(r)/r$ , we compute $i\partial \overline {\partial } \Phi $ ,
Combining with Proposition 3.3, we obtain
Now, we find $\Phi \in C^\infty (L^\times )$ such that $\omega = dd^c \Phi $ . It suffices to prove that $\Phi $ can extend smoothly across the zero level of L. To prove this, we need to apply a basic fact from complex functions: Let $f: [0,\infty ) \rightarrow \mathbb {R}$ be a smooth function, then, $g(z)=f(|z|)$ is smooth in $\mathbb {C}$ if and only if there exits a smooth function $h: [0,\infty ) \rightarrow \mathbb {R}$ such that $f(r)=h(r^2)$ . Since $\omega $ is defined in the whole line bundle L, on each fiber, the terms of $\omega $ ,
can extend smoothly across the zero level. Notice that $\mu \wedge \eta _0 = Cr^{-2} du \wedge d\overline {u} $ , where u denotes the fiber coordinate of L. Then, it is easy to see that the terms in (3.22) is smooth on each fiber if and only if $r^{-1}\varphi '(r)$ and $\varphi (r)$ are smooth on $\mathbb {C}$ if and only if there exists a smooth function $h: [0,\infty ) \rightarrow \mathbb {R}$ such that $h(r^2)=\varphi (r)$ . According to the definition of $\Phi $ , we expand $\Phi $ near $0$ :
we have
We claim that $C_{-1}$ is vanishing. Otherwise, $\varphi (0)\ne 0$ , which implies that $\varphi _0 (r) \eta _0$ is not well-defined on the zero level. Recalling the expression of $\theta $ , this contradicts against the fact that $\theta $ is well-defined on L. Therefore, we find a global Kähler potential for $\omega $ , which completes the proof.
Remark 3.5 The invariant $\partial \overline {\partial }$ -lemma does not hold for all line bundles. For instance, let $\alpha $ be a simple root with $\alpha =2 \lambda $ , for instance, the line bundle $\mathcal {O}(1)\rightarrow \mathbb {C}\mathbb {P}^1$ . Consider the following invariant 1-form:
Then, we can check that $d\theta $ is an invariant exact real (1,1) form. However, comparing with (3.21), there is no potential function for this form.
3.4 Proof of Theorem A
Firstly, it is easy see that the invariant $dd^c$ lemma can be applied when L is a negative line bundle over X. Notice that the homogeneous line bundle L can shrink to the base manifold X. Furthermore, we can require the shrinking process to be G-equivalent. In particular, we have the following isomorphism between cohomology groups:
which implies that all invariant Kähler classes of L arise from the invariant Kähler classes of X. In each invariant Kähler class of X, there exists exactly one invariant Kähler form, which follows directly from $dd^c$ -lemma on X. Given an invariant Kähler form $\omega $ on L, by previous discussion, there exists an invariant Kähler form $\omega _X$ on X such that $[\omega ]=p^*[\omega _X]$ then, by Propositions 3.4, there exists a smooth function $\Phi $ defined on L such that
Hence, we complete the proof of Theorem A.
4 Momentum profiles and the classification of invariant scalar-flat Kähler metrics
This section is dedicated to the proof of Theorem B. Our main tool of this section comes from [Reference Hwang and Singer22], in which the momentum construction is applied to investigate the Calabi ansatz. In Section 4.1, we will build up momentum construction by tracking the idea in [Reference Hwang and Singer22]. Then, momentum construction will be applied in Section 4.2 to get the existence and uniqueness of G-invariant scalar-flat Kähler metric. We also prove the scalar-flat Kählers are asymptotically conical metrics. This proves Theorem B.
4.1 Momentum construction of Calabi ansatz
Let $(X,\omega _X)$ be a Kähler manifold and $\pi :(L,h)\rightarrow (X, \omega _X)$ be a holomorphic line bundle of M with Hermitian metric h. Let t be the logarithm of fiber norm function related to h; i.e., given a local line bundle coordinate chart $(u,v)$ , where u represents the fiber coordinate, $t=\log [r(u)^2]:=\log h(u,\overline {u})$ . Then, Kähler metrics arise from Calabi ansatz is given by
where f is a smooth function of one real variable. According to Theorem A, all invariant Kähler metrics comes from Calabi ansatz (4.1).
It is well-known that the problem of prescribed scalar curvature is equivalent to a fourth-order PDE of potential function, specially, in this case, a fourth-order ODE. However, Hwang and Singer comes up the method of momentum profile in [Reference Hwang and Singer22] by which it can be reduced to be a second-order ODE, as the curvature formula related to momentum profile is of second order. In the following, we study the momentum profile associated with the given original data.
The Kähler metric, $\omega $ , arising from Calabi ansatz (4.1) may not exist in the whole line bundle L. For instance, in some cases, it might be blowing up in a finite domain with respect to fiber coordinate. We use $L'$ to denote the possible existence region of L for $\omega $ . Notice that Kähler metric $\omega $ constructed in (4.1) admits a natural Killing field $X_0$ , which generates a circle action on each fiber and can be written in local bundle coordinates, $X_0=r J({\partial }/{\partial r}).$ In aspects of symplectic geometry, $X_0$ generates a Hamiltonian action on $(L,\omega )$ by
At each point on $p \in X$ , there exists a coordinate chart around p such that $\partial \log h |_p=\overline {\partial } \log h|_p=0$ . By computing $\omega $ at each point in the chart,
and inserting (4.3) into (4.2), we have $\tau =f'(t)$ . Let the interval I be the image of moment map $\tau $ . Noting that $||X_0||_\omega $ is a constant along each level of $\tau $ , we can define the function $\varphi : I\rightarrow \mathbb {R}_{\geq 0}$ by factoring through $\tau $ ,
The interval I together with the function $\varphi $ is called momentum profile related to $(L',\omega )$ . The essential relation between $\varphi (\tau )$ and the potential f is given by
Also by observing (4.3), the positivity of Kähler form implies the following two things: f is a convex function; hence the moment map $\tau =f'(t)$ induces a Legendre transformation from t to $\tau $ . Moreover, if we denote $\gamma =-i\partial \overline {\partial } \log h$ , the positivity of $\omega $ also requires $\omega -\tau \gamma $ to be positive. An interval, I, is defined to be a momentum interval if for all $\tau \in I$ , $\omega (\tau )=\omega -\tau \gamma $ is positive. In the following, we shall reconstruct $(L',\omega )$ by momentum profile $(I,\varphi )$ with a momentum interval I and $\varphi : I\rightarrow \mathbb {R}_{\geq 0}$ .
Based on the inverse Legendre transformation, we can rebuild the Kähler metric $\omega $ explicitly by momentum profile $(I, \varphi )$ as follows. Let $(a,b)$ be the interior of I with $-\infty \leq a<b\leq \infty $ and fix $\tau _0\in I$ .
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(a) Fiber domain: Let T be the defining domain of $f(t)$ with $T^\circ =(t_1,t_2)$ , then,
$$ \begin{align*} t_1=\lim_{\tau\rightarrow a+}\int_{\tau_0}^\tau \frac{dx}{\varphi(x)}\quad \text{ and }\quad t_2=\lim_{\tau\rightarrow b-}\int^\tau_{\tau_0}\frac{dx}{\varphi(x)}. \end{align*} $$ -
(b) Potential function: $f(t)$ is given by data $(I,\varphi )$
$$ \begin{align*} f(t)=\int^{\tau(t)}_{\tau_0}\frac{xdx}{\varphi(x)}. \end{align*} $$ -
(c) Fiber metric: The metric $\omega $ induces the metric on each fiber in terms of coordinate u, $\displaystyle g_{\text {fiber}}$ and the $\omega $ -distance between $\tau _0$ level and $\tau (t)$ level, $s(t)$
$$ \begin{align*} g_{\text{fiber}}=\varphi(\tau)\bigg|\frac{du}{u}\bigg|^2, \qquad s(t)=\int_{\tau_0}^{\tau(t)}\frac{dx}{2\sqrt{\varphi(x)}}, \end{align*} $$
where the formulas in (b) and (c) can be obtained by change the variable though Legendre transformation.
The next step is to work out the curvature formula in terms of momentum profiles. To make curvature formula fit in the momentum profile, define $(\tau ,\pi ): L'\rightarrow I\times X$ . Here are some notations that will be used in the following:
-
• Let $\omega _\varphi $ represent the Kähler metric constructed by momentum profile $(\varphi ,I)$ , and we can rewrite (4.3) in terms of $\tau $ ,
(4.5) $$ \begin{align} \omega_\varphi =p^*\omega_X(\tau)+\varphi(\tau)\frac{idu\wedge d\overline{u}}{|u|^2}, \end{align} $$where $\omega _X(\tau ) = \omega _X -\tau \gamma $ . -
• Let B denote the endomorphism $\omega _X^{-1}\gamma $ , $\rho _X$ be the Ricci curvature form of X, define the following functions on $I\times X$ :
$$ \begin{align*} Q(\tau)&=\det(I-\tau B),\\ R(\tau)&=\operatorname{tr}[(I-\tau B)^{-1}(\omega^{-1}_X\rho_X)]. \end{align*} $$
Then, the Ricci curvature, Laplacian and scalar curvature have the following representation in terms of momentum profile and notations above:
-
• The Ricci form of $\omega _\varphi $ ,
(4.6) $$ \begin{align} \rho_\varphi=p^*\rho_X-i\partial\overline{\partial}\log \varphi Q(\tau). \end{align} $$ -
• Scalar curvature $S_\varphi $ ,
(4.7) $$ \begin{align} S_\varphi =R(\tau)-\Delta_{\omega_{X(\tau)}}\log Q(\tau)-\frac{1}{Q}\frac{\partial^2}{\partial \tau^2}(\varphi Q)(\tau). \end{align} $$
In the case of G-invariance, $ Q(\tau )$ is a polynomial in $\tau $ and $\Delta _{X(\tau )}\log Q(\tau )=0$ . Then, we can assume that $R(\tau )=P(\tau )/Q(\tau )$ for some polynomial P in $\tau $ . Therefore, we reduce the problem of prescribed scalar curvature to a second-order ODE
4.2 Proof of Theorem B
In the following, we compute the explicit formula of the polynomials $Q(\tau )$ , $P(\tau )$ in terms of $\omega _X$ and corresponding weight $\lambda $ . Recall the formulas (2.14) and (3.9) and $\omega _X$ , $\gamma $ can be expressed in terms of $dz_\alpha =\eta _\alpha +i \xi _\alpha $ and $d\overline {z}_\alpha = \eta _\alpha - i\xi _\alpha $ ,
where $S\in \mathfrak {s}$ such that $C_{\alpha ,S}>0$ . Then, the matrix B is diagonal, and $Q(\tau )$ has the following expression:
Since the Ricci curvature $\rho _X$ has the expression
Then,
Hence, the ODE (4.8) can be rewrite as follows:
To determine the initial data of the ODE (4.9), we need to apply the following completeness proposition in [Reference Hwang and Singer22, Propositions 2.2 and 2.3].
Proposition 4.1 [Hwang and Singer [Reference Hwang and Singer22]] Let $(I,\varphi )$ be a given momentum profile. Then the associated fiber metric is complete if and only if the following conditions hold at each endpoint of $I$ :
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• Finite Endpoints: $\varphi $ satisfies one of the following conditions:
-
(i) $\varphi $ vanishes to first order with $|\varphi '|=1$ ; or
-
(ii) $\varphi $ vanishes to order at least two.
-
-
• Infinite Endpoints: $\varphi $ grows at most quadratically, i.e., $\varphi \leq K\tau ^2$ .
And the corresponding $(L',\omega )$ behaves differently under different decay conditions provided in Proposition 4.1. We conclude the corresponding relations in the Table 1, where we consider finite ends at $\tau =0$ and infinite ends as $\tau \rightarrow \infty $ . The proof of these bundle behaviors directly follows from the reconstruction of the data $(L',\omega )$ by moment profile $(\varphi ,I)$ , (a)–(c).
To fit in our cases, we define the momentum interval $I=[0,b)$ with $b\leq +\infty $ . The reason we take the left ends to be $0$ is to ensure $\omega |_{X}=\omega _{S}$ . Assume that the corresponding scalar curvature of $\omega _\varphi $ is constant. Combining with Proposition 4.1 and Table 1, we shall solve the ODE with initial condition $\varphi (0)=0$ , $\varphi '(0)=1$ , and $S_\varphi =0$ . It is obvious that there is a unique solution $\varphi $ satisfies (4.9) and the initial condition.
4.2.1 The asymptotic behavior of scalar-flat Kähler metrics
In the scalar-flat cases, $\varphi $ satisfies
Assuming that $\lambda $ is negative, $\varphi $ is a strictly increasing function with initial value ${\varphi (0)=0}$ with degree one. According to Table 1, $\omega _\varphi $ is well-defined over the whole bundle $L_\lambda $ . By solving the ODE (4.9), the leading coefficient of the solution is given as follows:
We call $i_{\lambda , X} $ the metric index of line bundle of $(L_\lambda , X)$ . Recall the Kähler metric associated with $\varphi $ is given as in (4.5). Let $g_X(\tau )$ , $g_X$ , $g_\gamma $ be the metric corresponding to $\omega _X(\tau ) = \omega _X - \tau \gamma $ , $\omega _X$ , $-\gamma $ , respectively, then
where $\mu $ and $\eta _0$ are the dual of $r\partial /\partial r$ and $X_0$ , respectively. Then, on each level set of L, $M(\tau )$ , there is a metric induced by $g_\varphi $ , denoted by $g(\tau )$ ,
Let $C_\lambda $ be the cone associated with $L_\lambda $ by collapsing the base manifold X. Then, we should determine the radial function l of cone $C_\lambda $ such that the scalar-flat Kähler metric is asymptotically conical to $A i\partial \overline {\partial } l^2$ , where A is the constant coefficient and can be canceled by rescaling. Based on the discussion in Section 4.1, we have the following relationship between $\tau $ and t:
where the second equality is just the Taylor expansion of $1/\varphi (x)$ . Taking exponential and solve for $\tau $ , we can see that $\tau $ admits the following expansion at infinity:
Now, let $l=r^{i_{\lambda ,X}}$ , then the model Kähler metric over $C_\lambda $ is defined by the radial function l,
Rewrite the model Kähler form in terms of metric,
And the metric can be represented by $dl$ as follows:
Therefore, all scalar-flat Kähler metrics on $L_\lambda $ are asymptotically conical to $(C_\lambda , g_{\text {mod}})$ , which complete the proof of Theorem B.
In general, $g_\varphi $ decays to $g_{\text {mod}}$ by order $-2$ , which can be improved in some special cases. For instance, let the base metric $\omega _X $ be equal to the curvature form $\gamma $ , then, the similar calculation shows that the metric $g_\varphi $ with scalar-flat curvature decays to order $-2n+2$ .
Acknowledgments
The author would like to thank Professor Hans-Joachim Hein and Professor Bianca Santoro for suggesting the problem, and for constant support, many helpful comments, as well as much enlightening conversation.