Sken and cluster algebras of punctured surfaces

Abstract: We prove the full Fock-Goncharov conjecture for $\mathcal{A}{SL_2,\Sigma{g,p}}$--the $\mathcal{A}$-cluster variety associated to representation of $SL_2$ local systems on most punctured surfaces with at least 2 punctures in the classical $q\to 1$ setting, that is, the tagged skein algebra coincides with the upper cluster algebra (namely $Sk^{ta}=U(\Sigma)$ or $mid(\mathcal{A})=up(\mathcal{A})$), with methods being potentially useful to tackle the quantum case. We deduce similar results for the Roger Yang skein algebra via a birational geometric description, obtaining $Sk^{RY}=U(\Sigma)[v_i^{\pm1}]$ as conjectured by Shen, Sun and Weng, proving important algebraic properties of $Sk^{RY}$ including normality and Cohen-Macaulayness. Our result is complementary to what and Mandel and Qin have shown in arXiv:2301.11101 for surface with marked points, based on arXiv:1411.1394 . The once-punctured case where cluster structures are significantly different is also discussed in the paper, and relevant conjectures are proposed (and proved in the once-punctured torus case). By contrast, we define the ordinary cluster algebra with potentials added $A(\Sigma)[v_i^{\pm1}]$, introduced by Shen, Sun and Weng, which is shown to be usually smaller than $Sk^{RY}$ and $U(\Sigma)[v_i^{\pm1}]$. This strengthen the result of arXiv:2201.08833 that the classical $A=U$ fails for $\Sigma_{g,p}$ with $g\geq 1, p\geq 1$.