4 17. ENTROPY, μ-INVARIANT, AND FINITE TIME SINGULARITIESLEMMA 17.1 (Logarithmic Sobolev inequality). Let (Mn,g) be a closed
Riemannian manifold. For any a > 0, there exists a constant C (a, g) such
that if <p > 0 satisfies JM <p^2 dμg = 1, then(17.16) JM <p^2 log<pdμg:::; a JM jV'<pj~dμg + C(a,g),
where^1(17.17)2C ( a,g ) _ -aVo l ( g )-2/n + 4ae2Cs(M,g)" n
Here Cs (M,g) denotes the L^2 Sobolev constant, which we define to
be the best (largest) positive constant such that (see Lemma 2 in [114])
(17.18)
n-2
JM jV'<pj~dμg;::;,: Cs (M,g) (JM <p_;;::2dμg)--;;;- -Vol(g)-~ JM <p^2 dμgfor any C^00 function <p on M.
We have the following elementary properties.LEMMA 17.2 (Sobolev constants under scaling the metric). Let (Mn,g)
be a closed Riemannian manifold.
(i) The L^2 Sobolev constant has the property that for any .A.> 0,Cs (M, .A.^2 g) =Cs (M, g).
(ii) The logarithmic Sobolev constant has the property that for any a >
0 and .A. 2: 1,
C(a,.A.^2 g) :'.S:C(a,g).PROOF. (i) Let g = .A.^2 g and (jJ = ,A-n/^2 <p. Then dμ9 = .A.ndμg, <p^2 dμ9 =
<p^2 dμg, andJM 1v<p1; dμg = A-2 JM jV'<pj~ dμg
n-2
;::;,: .A.-^2 Cs (M,g) (JM <pn2
::2dμg )----,;:---- .A.-^2 Vol (g)-~ JM <p^2 dμg
n-2
=Cs (M,g) (JM <pn2
::2dμ9 )----,;:---- Vol(g)-~ JM (jJ^2 dμ9.
From this we can easily deduce that(17.19) Cs (M, .A.^2 g) =Cs (M, g)'
i.e., the L^2 Sobolev constant is invariant under scaling the metric.
(^1) 1n (17.17) we correct formula (6.67) in Part I, where the n (^2) /4 factor originally
appeared in the denominator; after (6.66) it should read Cn = 2 ~.