- SPATIAL POINT PICKING METHODS 53
REMARK 18.16. Thus, relative to the curvature at the center, we have
uniformly bounded curvature on balls oflarger and larger radii by (i) and (ii).
This conclusion is essentially the same as in Theorem 18.10 and Proposition
18.13.PROOF. (i) DefineFk (w) ~ Rhk (w) (D + 1-dhk (w, Ok))^2
for w E Bhk (Ok, D + 1). Note that Fk = 0 on 8Bhk (Ok, D + 1) and
sup Fk (w) ~ sup Rhk (w)---+ oo
Bhk(Ok,D+l) Bhk(Ok,D)
as k ---+ oo. We choose Wk E Bhk (Ok, D + 1) to be a point which satisfies
Fk (wk)= sup Fk (w).
Bhk (Ok,D+l)Let Bk~ ( 1-~) (D + 1-dhk (wk, Ok)). Then
Rhk (wk) B~ = (~ -V2) Fk (wk)---+ oo
as k ---+ oo. This proves ( i).
(ii) For any w E Bhk (wk, Bk) C Bhk (Oki D + 1) we have by the triangle
inequalityso thatIt follows thatRhk (w) B~ ( )^2 2
2 ::=; Fk(w) ::=; Fk Wk = Rhk (wk) Bk 2
(V2-1). (V2-1)
and hence Rhk (w) ::=; 2Rhk (wk) for all w E Bhk (wk, Bk). This proves the
lemma. 02.4. Dimension reduction for ancient solutions.
Dimension reduction is useful in the study of finite time singularity mod-
els. Recall that such solutions are ancient and, when their dimension is 3,
have nonnegative curvature operator. In this subsection we first give a cri-
terion for when an ancient solution on a manifold of a certain dimension
reduces effectively to a solution on a manifold of one less dimension. As
a consequence, we prove a dimension reduction result for /\;-solutions with
ASCR = oo. In the last part of this subsection we mention Hamilton's
'curvature bumps' theorem.