Peng Zhou

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blog:2023-03-30 [2023/03/30 07:39] pzhoublog:2023-03-30 [2023/06/25 15:53] (current) – external edit 127.0.0.1
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 If we considering $W_A = \eta(x+y+z-1)$, so $m_1, \cdots, m_4$. They are basis of the $M_A$. we need to have $n_1, n_2, n_3, n_4$ for compactification, so that we get If we considering $W_A = \eta(x+y+z-1)$, so $m_1, \cdots, m_4$. They are basis of the $M_A$. we need to have $n_1, n_2, n_3, n_4$ for compactification, so that we get
  
- +==== Simplest ==== 
 +What's the Fukaya category of $(\C, z^2)$? Well, you can try to view it as $(\C^*, z^2)$ deformation. The former has mirror $[\C / \Z_2]$. Then, you put in a divisor, and you turn on a superpotential. What superpotential do you want to turn on? I guess it is like $[ (\C, z^2) / \Z_2]$. The reason is $MF(\C, z^2)$, I know its critical loci is one point, so Vect (but I am not sure why quotient by $\Z_2$ doesn't give it more structure.  
 + 
 +No, I think it should be $MF([\C / \Z_2], w)$, where $w$ is the coordinate after quotient.  
 + 
 +Consider the Fukaya category of $(\C, z^n)$, then it is the representation of $A_{n-1}$ quiver (with n node and n-1 arrows). However, if we view it as $(\C^*, z^n)$ deformation, then we are making it affine, namely $n$-node with with $n$ arrows making it a circle quiver.  
 + 
 +==== Another one ==== 
 +What's the Fukaya category of $(\C^2, y x^2)$? Not a nice Lefschetz fibration. Don't even know the definition. But, the stop should be a Legendrian curve.  
 + 
 +How about, just $Fuk(\{x^2=0\})$? 
  
  
blog/2023-03-30.1680161965.txt.gz · Last modified: 2023/06/25 15:53 (external edit)