2. REDUCED VOLUME AT THE SINGULAR TIME FOR TYPE I SOLUTIONS 151
Integrating (30.69) over [f, w] yieldsdg(f) h'1(f), 1'2(f)):S4B!(w-f)! (2nVM+jf(x 1 ,f)+~+jf(x 2 ,f)+~)
- 1
+ 2 const ( w - t ) 2.
Therefore estimate (30.63) follows since X1=1'1(f) and x2=1'2(f).
Finally, (30.64) follows from taking x 1 = p and x 2 = x in (30.63) and from
applying (30.59). DNow we can apply the estimate above to the sequence used to define the reduced
distance £ 00.PROPOSITION 30 .18. Under the hypotheses of Theorem 30.13 we have that for
any c E (0, w^00 ;°'^00 )(30.70) d;oo(t) (x,poo) - c < f (x t) < cd;oo(t) (x, poo) + c
C (w 00 - t) -^00 ' - W 00 - t '(30.71) IV fool (x, t) :SC ( Jw~ _ t + dg::) ~~ x)),
(30.72)
I
f)foo I (x, t) :SC (d;oo(t) (p, ~) + 1 )
fJt (w 00 - t) Woo - ton M 00 x (a 00 + c, w 00 ) for some C < oo. Analogous estimates hold for a reduced
distance based at the singular time of a single Type I solution.PROOF. Applying inequalities (30.64) and (30.47) to (Mf,gi (t) ,pi), t E [ai, wi],
in the hypothesis of Theorem 30 .10, we have that for a ny (x, t) E M 00 x [a 00 +c, w 00 )
d~;(t) (x,p 00 ) _ Cd~;(t) (x,p 00 )
C ( ) - C :::; fi(x, t) :::; + C ,
Wi - t Wi - t
where C < oo is independent of both (x, t) and i and where i is sufficiently large.Hence, taking the limit as i-+ oo, we obtain (30.70).
R ecall from Theorem 30.lO(i) that £ 00 is locally Lipschitz. By applying (30.60)and (30.61) to fi defined in Theorem 30 .10 and then taking the limit of ii, we obtain
(30.71) and (30.72), respectively. DNow we can give thePROOF OF THEOREM 30.13. (1) V 00 (t) :::; l. For each i the reduce d volume
of the solution gi (t) based at (pi,wi ) is
(30.73)Since each solution gi (t), t E [ai,wi], is complete with bounded curvature, by
Lemma 8.16(ii) in Part I we have that each Vi (t) is integrable. Moreover, by
Theorem 8.20 and Corollary 8.17, both in Part I, we also have that each Vi (t) is