- PERELMAN'S K:-SOLUTION ON THE n-SPHERE 101
where Re - denotes the Ricci tensor of ?fL· We then compute
-d d Rmax ,,.._ :S 2 max 1-12 Re
t xEO'= 2max (IRc-.!.ii9L1
2
+ .!.ii2
xEO' n n )::::; ~ (1+11) ( Rmax )2,
where n' = n' (t) ~ { x E sn: R (x, t) = Rmax (t) }· Integrating the inequal-
ity
d ( ,,.._ )-1 ( ,,.._ )-2 d ,,.._ 2
dt Rmax = - Rmax dt Rmax 2: --;;;, (1+77)from -1 to 0, while using limt-+O Rmax (t) = oo, we obtain
(19.36)"' nRmin (-1) 2: 2 (l + ry)"
By applying (19.28) at t = -1, i.e.,
maxsn sect (g L ( -1))
8
minsn sect (?JL(-1)) ::::;1
+
to (19.35) and (19.36), i.e.,
n ,,.._ n
2 (l+ry) :SRmin(-1) :S 2'we conclude that the sectional curvatures of ?fL (-1) are close to 2 (n~l);
intuitively, ?f L ( -1) is metrically close to the round sphere metric of radius
J2 (n -1). ·
(ii) Second we note the changing distances estimate for ?fL(t):f) ,,.._
(19.37) at dt(X, y) 2: -4 (n - 1)-1-to(L) n
(L)for t ::::; -1 and x, y E S ,
t - towhere dt denotes the distance function for ?fL (t).
To see this, recall that by Theorem 18.7(2), for a solution (Mn, g (t)) of
the Ricci flow, if
Rc(x, to) ::::; (n - l)K
for all x E Bg(to) (xo,K-^112 ) UBg(to) (x1,K-^1 l^2 ), then the distance function
dg(t)(xo, x1) satisfies the following differential inequality (at time t =to):
:t lt=to dg.(t) (xo, x1) 2: -4 (n - 1) VK.
To obtain (19.37), by Rm 2: 0 and (19.33), it suffices to choose
K ( t) = -1 - to ( L).
t - to (L)