(Co)Homology of Lie Algebras via Algebraic Morse Theory

Abstract

E. Sk\"oldberg's Morse Theory from an Algebraic Viewpoint and M. J\"ollenbeck's Algebraic Discrete Morse Theory and Applications to Commutative Algebra, which is the algebraic generalization of R. Forman's discrete Morse Theory for Cell Complexes, is discussed in the context of general chain complexes of free modules. Using this, we compute the Chevalley-Eilenberg (co)homology of the Lie algebra of all triangular matrices soln over Q or Zp for large enough prime p. We determine the column and row in the table of Hk(soln;Z) where the p-torsion first appears. Every Zpk appears as a direct summand of some Hk(soln;Z). Module Hk(soln;Zp) is expressed by the homology of a chain subcomplex for the Lie algebra of all strictly triangular matrices niln, using the K\"unneth formula. All conclusions are accompanied by computer experiments. Then we generalize some results to the more general Lie algebras of (strictly) triangular matrices gln and gln with respect to any partial ordering on [n]. Furthermore, the matchings used can be analogously defined for other Lie algebra families and are useful for theoretical as well as computational purposes.