Date: Mon, 23 Dec 2002 01:12:43 -0500
From: Dylan Thurston <dpt@math.harvard.edu>
I'm afraid it will be a little time before I
can make substantive comments, as it is quite a long book... I was
particularly interested in your "Magic Triangle". If I understand
correctly, the central claim/conjecture of this triangle is that there
are diagrammatic calculi which specialize to give each row in the
triangle. This is quite remarkable, especially if these diagrammatic
calculi themselves fall into a series, as suggested by two things: the
symmetry of the magic triangle around the main diagonal; and the
similarity between the Diophantine equations you end up solving. The
first part is mainly missing a proof that the elementary graphical
relations you write down are enough to reduce arbitrary diagrams; and
the second part seems to still be numerology (but highly intriguing
numerology). Is this a good summary?
(PC 1 Aug 2007: that's fair.)
There are a couple of references that might be relevant to your work
(and that weren't in your bibliography):
Hans Wenzl, "On Tensor Categories of Lie Type E_N, N \ne 9", to appear
in Advances in Mathematics, available from http://math.ucsd.edu/~wenzl/
Jacob Lurie, "On simply laced lie algebras and their minuscule
representations", undergraduate thesis, Harvard University, 2000;
also Comment. Math. Helv. 76 (2001), no. 3, 515--575.
These both consider exceptional Lie algebras from the point of view of
their _miniscule representations_: the representation with the
smallest dimension. Hans shows that the invariants (for the "quantum"
groups in addition to the classical ones) are nearly generated by a
single tensor in dimension N (on the nose for N=6,7, and in a direct
summand for other N, N != 9). I think Jacob does something similar,
but more explicitly, for E_6 and E_7.
(PC 1 Aug 2007: all of this now promoted to a higher level of limbo, into the \Preliminary{ parts of the webbook manuscript} )
Dylan Thurston