1547845440-The_Ricci_Flow_-_Techniques_and_Applications_-_Part_III__Chow_

BOUNDS OF THE HEAT KERNEL FOR AN EVOLVING METRIC 353

by (26.52). Second, we compute

r 2 d~(O) (x,/C) }/Ci v (x, r) e Dr dμg(T) (x)

:::; C

4 ~~

2 r V^2 (x, 7) dμg(T) (x) ... ln-int(N 2 i-l R(JC))

since JCi c D - int (N 2 i-1 R (JC)) and d 9 (o) ( x, JC) ~ 2i R for x E JCi. Now

1

v^2 (x, r) dμ 2A ( 4i-1R2)

S1-int(N^9 (^7 ) (x) :::; - exp -B -

2 i-lR(JC)) f (r(y) 2CoT

by (26.60).
Combining all of the above estimates, we obtain
r 2 d~(O) (x,/C)

Jn v (x, r) e Dr dμg(T) (x)

. 1 R^2 2A^00 4iR^2 ( 4i-l R^2 )

< --eDr + Lel5T exp -B -

f(r) f (r/y) i=l ·. 2Cor

1 R^2 2A ~ R^2 4i(1-BP) = -_-eDr + - ~ eDr BCo •

f (r) f (^7 /'y) i=l

R2
Taking R so that eDr = 2, we conclude

1

d~(O) (x,/C) 2 2A^00 4i (i-Bp) v^2 (x, r) e Dr dμg(T) (x) :S; ---+ _ L 2 sco. n f ( r) f ( r I I) i=l

Now choose D =^1 6f 0 , so that

r 2. d~(O) (x,IC)

Jn v (x, r) e Dr dμg(T) (x)

2 2A f 2 _ 4 i :::; f (r) + f (r/1) i=l 8+A

< -

4f (r/1)
4A
<----

f(r/1)

since 2::~ 1 2_^4 i:::; ~' J (r/1):::; J (r), and A~ 1. Thus we have

{ 2 d~(o) (x,IC) 4AeCT Jou (x,r)e Dr dμg(T) (x) :S; f (r/i)'

where C ~ 2Co ( 1 - 1-^1 ). This completes the proof of Lemma 26.21. 0

< --eDr + Lel5T exp -B -