1549055384-Symplectic_Geometry_and_Topology__Eliashberg_

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LECTURE 3. THE WEINSTEIN CONJECTURE IN THE OVERTWISTED CASE 71

and

J(z,O)=i if lzl~l


where

F := {(z,azkl^2 ) E C^2 I z E 8D; a ER},

J(z, w) := Tcp(cp-^1 (z, w)) o J(cp-^1 (z, w)) o Tcp-^1 (z, w).

Here k is a suitable integer depending on F and w.

It is interesting to note that the number k for a disk occuring in our Bishop


family is 0.


Exercise 3.3. Show that given a disk map ii in the previously constructed Bishop


family the constant k occuring in the corresponding local normal form is 0.


The proof of theorem 3.2 is a bit technical and we will not give details. A proof
can be found in [1]. There the reader will also find an introduction of the Maslov
index for loops of totally real planes. In this framework the integer k above finds
its natural explanation.
By the results of the previous section the investigation of the solution set of
(12) near an embedded solution uo reduces to the following problem:


u: D -----+ c2 ,


(13) 81u 8u + J ( u) 8u = 0

8s 8t

on b,

u(8D) c F,


where J is an almost complex structure satisfying J(z, 0) = i for I z I~ 1 and


F = {(z, azkl^2 ) E C^2 I z E 8D; a E JR}


is totally real for J. We are interested in solutions u near the obvious solution


u 0 (z) = (z, 0) if k = 0. In order to understand the solution set of (13) we have to


view [) 1 as a smooth map between appropriate Banach manifolds.


c

c

Figure 9. This figure shows the situation if k = 0.
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