258 6. ENTROPY AND NO LOCAL COLLAPSING
we have injg(t) (p) 2: er.
Corollary 6.62, i.e., Perelman's no local collapsing theorem, implies that
if (Mn, g (t)), t E [O, T), is a solution of the Ricci flow on a closed manifold
with T < oo, then g(t), t E [O, T), satisfies a local injectivity radius estimate.
5.2.2. Proof of No Local Collapsing Theorem 6.58. The idea of the proof
is that if a metric g is K-collapsed at a point x at a distance scale r for K
small and r bounded, then W (g, f, r^2 ) is negative and large in magnitude,
e.g., on the order of log K, for f concentrated in a ball of radius r centered
at x. This contradicts the monotonicity formula for μ (g ( t) , r ( t)).
PROOF OF THEOREM 6.58 ASSUMING PROPOSITION 6.64. We shall say
that r is the (space) scale of μ (g, r^2 ); the justification for this terminology
occurs below. Since T /2 < T, by the remarks after Definition 6.55, there
exists Ko = 11);0 ( n, g ( 0) , T, p) > 0 such that g ( t) is Ko-noncollapsed below the
scale p for all t E [O, T /2].
On the other hand, if t E [T /2, T), then for any 0 < r :::; p, we have
t + r^2 E [T/2, T + p^2 ), and by the monotonicity formula (6.61), we have
μ (g (t), r^2 ) 2: μ (g (0), t + r^2 )
(6.82) 2: inf μ(g(O),r)~-Ci(n,g(O),T,p)>-oo
TE[T/2,T+p2]
since T < oo. In summary, by the monotonicity formula, since the μ-
invariant of the initial metric is bounded from below at scales bounded from
above and below, the μ-invariant of the solution after a certain amount of
time (say T /2) is bounded from below at all bounded scales. The theorem
will follow from the important observation that if a Riemannian metric is
K-collapsed at some scale r for K small, then its μ-invariant is negative and
large in magnitude at the time scale r^2 (see Proposition 6.64 below).
If x EM, t E [T/2,T), and r E (O,p] are such that /Rmg(t)/ :::; 1 in
Bg(t) (x,r), then Rcg(t) 2: -c1 (n)r-^2 and Rg(t):::; ci (n)r-^2 in Bg(t) (x,r),
where c1 (n) = n (n - 1). So by (6.82) and (6.83),
-Ci (n,g (0) ,T,p):::; μ (g (t) ,r):::;^2 log Volg(t) Bg(t) n (x, r) + C2 (n,p).
r
We conclude that
Volg(t) Bg(t) (x, r) > ( (O) T ) > 0
r n - K1 n, g ' 'P '
where K1 (n, g (0), T, p) = e-Ci(n,g(O),T,p)-C^2 (n,p). The theorem follows with
the choice K(n, g(O), T, p) ~ min{Ko, K1}. D
Now we turn to bounding the μ-invariant from above by volume ratios
in a Riemannian manifold.
PROPOSITION 6.64 (μ controls volume ratios). Let p E (0, oo). There
exists a constant C2 = C2 ( n, p) < oo such that if (Mn, g) is a closed