Non-commutative integrability, paths and quasi-determinants
Copyright policy )Non-commutative integrability, paths and quasi-determinants
In previous work, we showed that the solution of certain systems of discrete integrable equations, notably $Q$ and $T$-systems, is given in terms of partition functions of positively weighted paths, thereby proving the positive Laurent phenomenon of Fomin and Zelevinsky for these cases. This method of solution is amenable to generalization to non-commutative weighted paths. Under certain circumstances, these describe solutions of discrete evolution equations in non-commutative variables: Examples are the corresponding quantum cluster algebras [BZ], the Kontsevich evolution [DFK09b] and the $T$-systems themselves [DFK09a]. In this paper, we formulate certain non-commutative integrable evolutions by considering paths with non-commutative weights, together with an evolution of the weights that reduces to cluster algebra mutations in the commutative limit. The general weights are expressed as Laurent monomials of quasi-determinants of path partition functions, allowing for a non-commutative version of the positive Laurent phenomenon. We apply this construction to the known systems, and obtain Laurent positivity results for their solutions in terms of initial data.
46 pages, minor typos corrected
- University of Illinois at Urbana Champaign United States
- Department of Mathematics University of Michigan United States
- Centre national de la recherche scientifique France
- University of Michigan–Flint United States
- University of Illinois System United States
Cluster algebra, Mathematics(all), 05, 81, Continued fractions, FOS: Physical sciences, Quasi-determinants, Mathematics - Quantum Algebra, FOS: Mathematics, Mathematics - Combinatorics, Quantum Algebra (math.QA), quantum cluster algebra, Lattice dynamics; integrable lattice equations, noncommutative, Mathematical Physics, Cluster algebras, continued fractions, Mathematical Physics (math-ph), Path models, Quantum cluster algebra, quasi-determinants, discrete integrable systems, Noncommutative, Discrete integrable systems, Combinatorics (math.CO), path models, cluster algebra
Cluster algebra, Mathematics(all), 05, 81, Continued fractions, FOS: Physical sciences, Quasi-determinants, Mathematics - Quantum Algebra, FOS: Mathematics, Mathematics - Combinatorics, Quantum Algebra (math.QA), quantum cluster algebra, Lattice dynamics; integrable lattice equations, noncommutative, Mathematical Physics, Cluster algebras, continued fractions, Mathematical Physics (math-ph), Path models, Quantum cluster algebra, quasi-determinants, discrete integrable systems, Noncommutative, Discrete integrable systems, Combinatorics (math.CO), path models, cluster algebra
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