- WHEN BREATHERS AND SOLITONS ARE EINSTEIN 43
REMARK 1.69. A version of Corollary 1.68 for the Ricci tensor may be
proved directly from the evolution of the curvature operator eigenvalues,
using the maximum principle for systems. See [218] for details.COROLLARY 1.70 (Ricci flow on 3-manifolds: R bounds Rm). For anysolution ( M^3 , g ( t)) of the Ricci flow on a closed 3-manifold, if R is uni-
formly bounded, then IRml is also uniformly bounded.PROOF. If R ::::; C, then v 2: -C' for some constant C'. If .A 2: μ 2: v are
the eigenvalues of Rm, then R = .A + μ + v and .A ::::; R - 2v ::::; C + 20'. DA nice application of the Hamilton-Ivey estimate is the following (see
[218]).THEOREM 1.71 (Shrinking breathers on closed 3-manifolds are Einstein).
The only solitons (or breathers) for the normalized Ricci flow on a closed
connected 3-manifold M are constant sectional curvature metrics.The example of Koiso's shrinking soliton (see Section 7 of Chapter 2) shows
that this result cannot be extended to dimension 4.PROOF. By Proposition 1.66, either the metric is Einstein (which isequivalent to constant curvature in dimension 3) or Rmin > O; in the lat-
ter case, the breather is a shrinking breather. By Corollary 1.68, for the
unnormalized Ricci flow,
Rm > -'ljJ (R) id --t 0 as R --t oo
R - R '
and Rmin (t) --t oo as t --t T, where [O, T) is the maximal time interval of
existence. So the sectional curvature becomes asymptotically nonnegative
under the unnormalized flow. Since we assume our solution to be either a
soliton or a breather, the curvature must have been nonnegative to begin
with.
In [179], Hamilton has shown that either the sectional curvature be-
comes strictly positive immediately or M splits locally as a product of a
1-dimensional flat factor and a surface with positive curvature, and this
splitting is preserved by the flow. In the former case, we know g converges
to a metric of constant positive sectional curvature under the normalized
flow. To rule out the latter case, consider the evolution equation for r under
the normalized flow:
! J Rdμ= - j ( ~;,Rc-~Rg) dμ,
where the volume is fixed at one and the pointwise inner product is given by
contraction using the metric. We can calculate the integrand on the right
as