82 29. COMPACT 2-DIMENSIONAL ANCIENT SOLUTIONS
Recall that from (29.7) we have(29.49)
Hence we have that
(29.50)
DEFINITION 29.13. We say that a function ii E W^1 ,^2 is a weak solution of
the equation
(29.51)
if for any cp E C^00 (S^2 ) we have that
1
2(-ii (Vcp, Vii) - 2 IViil
2
cp + 2ii^2 cp) dμ 52 = o.By (29.50), showing that v 00 is a weak solution of (29.51) is equivalent to
showing that
1
2
(-voo (Vcp, Vvoo) - IVv 001
2
cp) dμ5 2 = 1
2
w 00 cpdμ52for any cp E C^00 (S^2 ). Now, since v 6.52V---+ Woo in C^0 -, we have
1
2
(-v(t) (Vcp, Vv(t)) -1Vv(t)l
2
cp) dμ52 = 1
2
(v6. 5 2v)(t)cpdμ 82---+ r Woocpdμ52.
Js2But since we have v(t)---+ Voo in C^1 '°', we also have
1
2
(-v(t) (Vcp, Vv(t)) -1Vv(t)l
2
cp) dμ 52---+ 1
2
(-voo (Vcp, Vvoo) - 1Vvool
2
cp) dμ5 2as t ---+ - oo. To summarize,
LEMMA 29.14. The limit v 00 E C^1 '°' is a weak solution toVoo6.s2Voo - 1Vvool
2
- 2v~ = 0.
By (29.7), this may be interpreted as saying that _.l_gVoo 82 has zero scalar curvature
in a weak sense.
In fact, we have that Voo is a strong solution in n = { x : Voo ( x) > 0} of S^2.
One way to see this is that v~ E C^3 '°' is a strong solution to
(29.52) u5A 2 ( Voo^2 ) - ~ IV(v~) 2 l2 +^2 Voo^2 =^0
4 vooin D. From a standard interior regularity theory, we obtain v~ E C^00 in D. There-
fore v 00 E C^00 in {x: v 00 (x) > O}.
PROBLEM 29.15. Can one directly show that (D, _.1_gVoo 82 In) is a complete metric?