Difference between revisions of "Some Questions About Trinions"

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'''{{Dror}}'s Speculation.''' If yes, it will have terrific consequences. If no, it will explain some of the misery we encounter when we deal with "associators". I would really like to understand this one.
 
'''{{Dror}}'s Speculation.''' If yes, it will have terrific consequences. If no, it will explain some of the misery we encounter when we deal with "associators". I would really like to understand this one.
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Of course, these questions all can and should be generalized to arbitrary knotted graphs.

Revision as of 18:35, 12 October 2006

This paperlet was born as 06-1350/Class Notes for Tuesday October 10.

Plastic trinions

Question 1. Can you embed a trinion (a.k.a. a sphere with three holes, a pair of pants, or a band theta graph) in {\mathbb R}^3 so that each boundary component would be unknotted yet each pair of boundary components would be knotted? How about, so that at least one pair of boundary components would be knotted?

Dror's Speculation. Yes and yes.

Question 2. A trinion \gamma is embedded in {\mathbb R}^3 so that its boundary is the trivial 3-component link. Does it follow that \gamma is trivial?

Dror's Speculation. No.

Question 3. Suppose two trinions \gamma_1 and \gamma_2 are knotted so that the pushforwards \gamma_{1\star}L and \gamma_{2\star}L are equal for any link L which is "drawn" on the parameter space \Gamma of \gamma_1 and \gamma_2. Does it follow that \gamma_1 and \gamma_2 are equivalent?

Dror's Speculation. I'm clueless.

The standardly embedded strapped trinion

Question 4. A trinion \gamma is embedded in {\mathbb R}^3 so that its "strapped boundary" is equivalent to the strapped boundary of the trivially embedded trinion. Does it follow that \gamma is trivial?

Dror's Speculation. If yes, it will have terrific consequences. If no, it will explain some of the misery we encounter when we deal with "associators". I would really like to understand this one.

Of course, these questions all can and should be generalized to arbitrary knotted graphs.