1547845439-The_Ricci_Flow_-_Techniques_and_Applications_-_Part_I__Chow_

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  1. THE ENTROPY FUNCTIONAL W AND ITS MONOTONICITY 225


i.e., the variation preserves the measure (47rT)-nl^2 e-f dμ on M, we obtain

from ( 6. 9) the gradient flow (assuming ~; = -1)
a
(6.10) at9ij = -2 (Rij + \7/\Jjf),
af n
(6.11) at = -f:lf - R + 2T,

(6.12) ~: = -1.


LEMMA 6.3 (Entropy monotonicity for gradient flow). If (g(t), f(t), T(t))
is a solution to the system (6.10)-(6.12), then
d

dt W(g(t), f (t), T(t))

(6.13)

PROOF. This follows directly from substituting

Vij = -2 (Rij + \li\ljf)'


n
h = -f:lf-R+ 2T'
( = -1
into (6.9) and using the facts

~ -h-;c = O and JM (!:lf-l\lfl


2

) e-^1 dμ = o.

D

1.2. Coupled evolution equations associated to W and mono-

tonicity of W.

1.2.1. The coupled evolution equations associated to W. As in Chapter
5, there is a system of evolution equations for the triple (g, f, T) (see (1.3)
of [297])

(6.14)

(6.15)

(6.16)

a
at9ij = -2Rij,
af · n
at = -f:lf + 1v11

2


  • R+ 27 ,


dT = -l
dt '
whose solution differs from the solution to (6.10)-(6.12) by diffeomorphisms.
This leads to the following theorem, which says that
d
dt W(g(t), f(t), T(t)) 2: 0.


Another motivation for studying this system of equations, from considering
gradient Ricci solitons, was discussed in Section 8 of Chapter 1.

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