- A GEOMETRY WITH ISOTROPY SO (3) 13
From the symmetry in these equations, we may assume without loss of
generality that Do :::; Co:::; Bo. The computation
!!:._ ( B - D) = 4 ( B - D) c2 - ( B + D) 2
& BCD
shows that the inequalities D :::; C :::; B persist for as long as the solution
exists. Thus we may assume that Bo - Do> 0. The estimate
d D- dt B < - -8+4-c < - - 4 )
implies that the solution exists only on a finite time interval; in particular,
there exists T < oo such that D '\, 0 as t / T. The estimate
!!:._ (B -D) = (B -D) C -D -B
2<
dt D^8 D CD - Oshows that Br/ :::; 8, where
Bo- Do
8 ~ Do > 0.Thus we have 0 < B - D:::; 8D for 0:::; t < T, whence the result follows. D
REMARK 1.18. When B = C = D at t = 0, this symmetry persists. It
follows easily that SU (2) remains round and shrinks at the rate
D (t) =Do - 4t =Do - 2 (n - 1) t.This is the 3-dimensional version of the 'shrinking round sphere' discussed
in Subsection 3.1 of Chapter 2.
Now we consider the 2-parameter family of metrics 9c: (t) obtained by
letting the an initial metric 9c: evolve by the Ricci fl.ow on a maximal time
interval 0 :::; t < Tc:. We will see that the Ricci fl.ow on SU (2) (in contrast
to the homogeneous geometries we shall consider below) strongly avoids
collapse. Instead of studying A, B , and C directly, it will be more convenient
to introduce quantities E , F defined by
B - C
E~B+C, F~.
E
Then the Ricci fl.ow of 9c: (t) is equivalent to the following system:(1.5a) !!:_A=
4
c (F^2 - A^2 )
dt BC
(1.5b) !!:_E = - 16 + ~ (A^2 - F^2 ) Edt ABC
(1.5c) !!:_p = _ 4 _ (cA2 -E2) F.
dt ABC EAs initial conditions, we posit A(O,r:;) =Ao> 0, E(O,r:;) =Bo+ Co> 0,
and without loss of generality F (0, r:;) = (Bo - Co) /r:; 2: 0. A solution of
this system exists as long as ABC E ( 0, oo). Our next observation is that
solutions exist on a common time interval, regardless of E.