128 5. THE RICCI FLOW ON SURFACES
Let N be a constant to be determined, and set
<J? ~ tk+3 lvkRl2 + Ntk+2 lvk-l Rl2
Then there are constants a, bj, and Cj such that we can estimate:t <J? ::::: L:\<J? + tk+^2 lvk Rl
2
[atR + (k + 3 - 2N)]
Lk/2J
+ Jtk+2 JVkRl2. L bjJtj+21vjRl2. tk-j+21vk-jRl2j=l
L(k-1)/ 2J
+ N L CjJtk+l JVk-l Rl^2. tH^2 J'Vj Rl^2. tk-j+l JVk-j-lRJ^2
j=O- N (k + 2) tk+l lvk-1 Rl2.
By the inductive hypothesis, there is a sufficiently large constant N depend-
ing only on g (0), and positive constants A, B, C, D depending on g (0) and
N such that:t <J?::::: L:\<J? -Atk+2 l'VkRl2 + BVtk+2 JVkRl2 + c::::: L:\<J? + D.
As in Lemma 5.32, this suffices to yield the result. D
Now that our proof of Proposition 5.33 is complete, Theorem 5.28 follows
readily.- Strategy for the case that x (M^2 > 0)
We have established Theorem 5.1 for surfaces such that r :::; 0. In the
remainder of this chapter, we tackle the far more difficult case that r > 0.
For the convenience of the reader, we now summarize the path we will take
to prove that the normalized Ricci flow on a surface of positive Euler char-
acteristic converges exponentially to a metric of constant positive curvature.7.1. The case that R (-, 0) 2:: 0. We first consider the special case
that the scalar curvature is initially nonnegative. By the strong maximum
principle, one then has Rmin (t) > 0 for any t > 0 unless R = 0 everywhere,
which is possible only if the initial manifold was a fiat torus. Hence (by
restarting the flow after some fixed time c > 0 has elapsed) we may assumethat R (., 0) > 0.
Recall that the trace-free part of the Hessian of the potential f of the
curvature is the tensor M defined in (5.9) as
1M = 'V'Vf- 2L\f · g,
where by (5.8), one has L\f = R - r. In Section 3, we observed that the
tensor M vanishes identically on a Ricci soliton. And in Section 4, we saw
that the only self-similar solutions of the Ricci flow on a compact surface