22 17. ENTROPY, μ-INVARIANT, AND FINITE TIME SINGULARITIESPROBLEM 17.21. In view of Proposition 17.20, can one determine themore precise asymptotic behavior ofμ (g, T) for T near O?
2.2. Possible nonuniqueness of minimizers of W for T small.
Proposition 17 .20 has the following consequence for the non uniqueness
of certain minimizers for T sufficiently small. This contrasts with the case
of the energy functional F, for which the minimizer is unique.LEMMA 17.22 (For small T the minimizer is nonconstant and may not
be unique). Let (Mn, g) be a closed Riemannian manifold.
(1) Any minimizer fr of W (g, · , T) cannot be a constant function for
T sufficiently small.(2) If the isometry group of (M,g) acts transitively, then for T suffi-
ciently small any minimizer fr of W (g, ·, T) is not unique.
PROOF. We prove both statements by contradiction.
(1) Suppose that there exists a sequence Ti ~ 0 such that for each i,
there is a minimizer fri of W (g, ·,Ti) which is constant. Then by (17.14),
i.e.,Ti ( 2D..fri - /\7 fri/^2 + Rg) + fri - n = μ (g, Ti)'
we have that Rg is constant. Hence we have for all i,μ (g, Ti)= TiRg + fri - n
(17.72)n
= TiRg -
21og (411"Ti) +log Vol (g) - n,where the second equality follows from the constraint in (17.8).^6 We obtaini,oo ,lim μ (g, Ti) = i,oo ,lim (TiRg - ~log 2 ( 411"Ti) +log Vol (g) - n) = oo
since Ti~ O. This contradicts (17.47).( 2) Let T be sufficiently small so that part ( 1) holds for ( M, g). Then
suppose that the minimizer fr of W (g, ·, T) is unique. Since the isometrygroup of g acts transitively on M, for every x, y E M there exists an isometry
</>:M~Mof the metric g with </> ( x) = y. By the diffeomorphism invariance of the
W-functional, we have that fro</> is also a minimizer of W (g, ·, T). Thus,
by our uniqueness assumption, fro</> = fn which implies fr (x) = fr (y).
Since x and y are arbitrary, we conclude that fr is constant, a contradiction
to our assumption on T. O
(^6) When fr is constant, the constraint JM (4nr)-n/ (^2) e-frdμ
-~log (4nr) +log Vol (g).
1 implies fr