Notes for AKT-170113/0:50:48: Difference between revisions

Roland At 38:12 Dror mentions a solution to CYBE already gives a knot invariant by setting ${\displaystyle R_{ij}=1+hr_{ij}+{\frac {1}{2!}}h^{2}r_{ij}^{2}}$ and working modulo ${\displaystyle h^{3}}$. Notice I added the ${\displaystyle h^{2}}$ term to make the inverse ${\displaystyle R^{-1}}$ be identical but with negative ${\displaystyle h}$, the factorial is just for fun. I wanted to test this idea in ${\displaystyle U(sl_{2})}$ where you can check that ${\displaystyle r_{ij}=E_{i}F_{j}+{\frac {1}{4}}H_{i}H_{j}}$ is a solution to CYBE. If I got it right the positive Reidemeister 1 curl yields the value ${\displaystyle 1+h(EF+{\frac {1}{4}}H^{2})+{\frac {1}{2}}h^{2}(2E^{2}F^{2}+EH^{2}F+EFH+{\frac {H^{4}}{8}})}$ bad news, we need the element ${\displaystyle S}$ to get an invariant in this case. Taking ${\displaystyle {\tilde {r}}_{ij}=r_{ij}+r_{ji}}$ we may do a little better in that now the curl yields ${\displaystyle 1+h(EF+FE+{\frac {1}{2}}H^{2})+{\mathcal {O}}(h^{2})}$ indicating our ambiguity may now be a central element (the Casimir at order h).