- EXTENSIONS OF HAMILTON'S COMPACTNESS THEOREM 139
for all k EN. We assume inj 9 k(o) (Ok) 2-: lo for some lo > 0. Then there exists
a subsequence {(Mk, gk (t), Ok)} which converges to a complete solution tothe Ricci flow (M~, g 00 (t), 000 ), t E (a, w).
REMARK 3.19. Note that the limit solution (M~, g 00 (t), 000 ) may not
have bounded curvature.
Without the injectivity radius estimate, we may use the trick of locally
pulling back the solutions by their exponential maps (since the pulled-back
solutions satisfy an injectivity radius estimate). We have the following.
COROLLARY 3.20 (Local compactness without injectivity radius esti-
mate). Let {(Mk', gk (t), Ok)}kEN, t E (a, w) 3 0, be a sequence of complete
solutions to the Ricci flow with
IRmklk:::::; Co in B 9 k(o) (Ok,P) x (a,w).
Then there exists a subsequence such that{ ( BTokMk (o, c) ' ( exp~k(O))* gk(t)) 'oLEN' where c ~min {p, 7r/vCo}'
converges to a pointed solution (J3~,g 00 (t),0 00 ), t E (a,w), on an openmanifold which is complete on the closed ball B 900 (o) (0 00 , r) for all r < c.
REMARK 3.21. There is a similar result for geodesic tubes; see §25 of
Hamilton [186].
3.2. Compactness for Kahler metrics and solutions. Without
much difficulty, the compactness theorems apply to Kahler manifolds and
solutions of the Kahler-Ricci flow (see also Cao [48] and Theorem 4.1 on
pp. 16-17 of Ruan [314]).
THEOREM 3.22 (Compactness for Kahler metrics). Let { (M~n, gki Ok)}
be a sequence of complete pointed Kahler manifolds of complex dimension n.
SupposeIV'~ Rmklk:::::; Gp on Mk
for all p 2-: 0 and k, where Gp < oo is some sequence of constants independent
of k, and
inj 9 k (Ok) 2-: lofor some constant lo > 0. Then there exists a subsequence {jk}kEN such that
{(Mjk,gjk,Ojk)}kEN converges to a complete pointed complexn-dimensional
Kahler manifold (M~, g 00 , 000 ) as k ---* oo. See the ensuing proof for the
meaning of the convergence of the complex structures Jk --t Joo.
PROOF. Since Kahler manifolds are Riemannian manifolds, we can ap-
ply the Cheeger-Gromov Compactness Theorem 3.9 to obtain a pointed
limit (M~, g 00 , 000 ) which is a complete Riemannian manifold. So the
only issue is to show that the limit is Kahler. Let Jk denote the complex
structure of (Mk, gk). We have for each k E N,
(1) Jf = -id™k'