- EXPONENTIAL CONVERGENCE 219
In particular, the eigenvalues>. ~ μ ~ v of M (which are twice the sectional
curvatures) evolve by
It is easy to check that
d •
. = >.^2 + μv - r >.
dt
d 2
dtμ=μ +>.v- rμ
d 2
dt v = v + >.μ - rv.d >.
[>. (μ + v)] -d log --= (μ + v) (>.^2 + μv) - r>. (μ + v)t μ+ v
. [μ^2 + v^2 + >. (μ + v) J + r >. (μ + v) ,
hence that the proof of Lemma 6.28 goes through for the normalized flow
exactly as written. Thus we can immediately state the following result.
LEMMA 6.65. Let (M^3 ,g(t)) be a solution of the normalized Ricci flow
on a closed 3-manifold of initially positive Ricci curvature. Then there exists
a constant B such that
>.:SB(μ+ v)for all positive time.
REMARK 6.66. One can also conclude directly that the estimate of
Lemma 6.28 applies to the normalized Ricci flow by writing it in the scale-
invariant form
.
--μ +v-<B.
We shall need one more simple observation.LEMMA 6.67. Let (M^3 ,g(t)) be a solution of the normalized Ricci flow
on a closed 3-manifold of initially positive Ricci curvature. Then there exists
c: > 0 depending only on go such that R ~ c: for all positive time.PROOF. By (6.6), R satisfies the differential inequality 8R/8t ~ b..R.
Hence Rmin (t) ~ Rmin (0) > 0. DNow we are ready for the key estimate of this section.PROPOSITION 6.68. Let (M^3 , g(t)) be a solution of the normalized Ricci
flow on a closed 3-manifold of initially positive Ricci curvature. Then there
exist constants a E (0, 1), /3, and C depending only on go such that
. - v :S C (μ + v)^1 -°' e-f3t
for all positive time.