For Grassmannians, the Schubert cells can be indexed by certain Young Tableaux, whose partition determines the dimensions of intersections of the chosen subspace with the standard complete flag. For example, up to change in convention, in $Gr(2,4)$, the subspace $V = \langle e_2,e_4\rangle$ may belong to $X_{(1,0)}$, since, if $F_\bullet$ is the standard complete flag, then $dim(V \cap F_j) = (0,1,1,2)$, while for a generic 2-dimensional subspace, $V_{gen}$, $dim(V_{gen} \cap F_j) = (0,0, 1,2)$. One scheme for associating the cells to partitions is to record the difference (between $V$ and $V_{gen}$) between the position of the first appearance of 1 in the "intersection dimension vector" as the first element of the partition, and the difference between the position of the first appearance of 2 as the second entry, hence $(1,0)$. (This was explained to me only one time in person, so please let me know if I've got some aspect of this process wrong.) So if I am given the algebraic data (partition), I can determine the geometric data (intersection dimension vector) and vice versa.
For complete flags, the Schubert cells are naturally indexed by $S_n$, which admits a bijection to pairs of same-shape standard Young tableaux via Robinson-Schensted correspondence. Is there a geometric understanding of these SYT's in a way analogous to the above? i.e. For $Fl(m)$, we have a $2\times m-1$ ($m-1$ if we ignore the final column, which will always just be $\begin{pmatrix} m \\ m \end{pmatrix}$) matrix of intersection dimensions, $dim(E_i\cap F_j)$ for $i,j \in \{1,2,\dots,m-1\}$. If I know the intersection dimension matrix of a certain flag, can I determine the pair of SYT of its Schubert cell or vice versa?
