1547671870-The_Ricci_Flow__Chow

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158 5. THE RICCI FLOW ON SURFACES


have


Cs (r) =Lg (r) 2 ( Ag (Mi)^1 +Ag (M§)^1 )


(5.47)

2 Ag (M2)


=Lg (r) Ag (Mi) ·Ag (M§)'


where Lg denotes length and Ag denotes area measured with respect to g.
Moreover, the infimum in Definition 5.80 is attained by a smooth embedded
curve.

LEMMA 5.82. If (M^2 , g) is a closed orientable Riemannian surface, there
exists a smooth embedded (possibly disconnected} closed curve/ such that

Cs (r) = Cs (M^2 ,g).


For a proof, see Theorem 3.4 of [ 69 ]. Analogous results in general di-
mensions can be found in Theorems 5-5 and 8-6 of [99].

REMARK 5.83. The minimizing curve r might be disconnected, as can
easily be seen by considering a rotationally symmetric 2-dimensional torus
with two very thin necks. In this case, / is the union of two disjoint embed-
ded loops. More generally, no connected embedded homotopically nontrivial
curve will separate a torus.

Now we restrict ourselves further to the case that ( M^2 , g) is diffeomor-
phic to 52. Define a loop in M^2 to be a connected closed curve. It follows
from the Schoenfiies theorem that any smooth embedded loop r separates
M^2 into smooth discs Mi and M§. We denote the isoperimetric ratio of a
smooth loop on a topological sphere by

Then we define
CH (M^2 ,g) ~inf CH (r),
'Y

where the infimum is taken over all smooth embedded loops r· Clearly,


Cs (M^2 ,g):::; CH (M^2 ,g).


If ( 52 , 9can) is a constant-curvature 2-sphere, then CH ( 52 , 9can) = 47r.
Moreover, this is an upper bound.

LEMMA 5.84. If (M^2 , g) is a closed orientable Riemannian surface, then


CH (M^2 , g) :::; 47r.


PROOF. Let x E M^2 be given and define

le~ {y E M^2 : distg (x,y) = c}.

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