Nonlinear Reformulation of Heisenberg's Dynamics

Abstract: A structural similarity between Classical Mechanics (CM) and Quantum Mechanics (QM) was revealed by P.A.M. Dirac in terms of Lie Algebras: while in CM the dynamics is determined by the Lie algebra of Poisson brackets on the manifold of scalar fields for classical position/momentum observables Q/P , QM evolves (in Heisenberg's picture) according to the formally similar Lie algebra of commutator brackets of the corresponding operators:where QP − PQ = ih. A further common framework for comparing CM and QM is the … Show more

“…The choice of the recursion operator is inspired by related recursion operators admitted by the KdV and mKdV equations. 13,15,27,19,40 Actually the relation ⌿͑V͒ = D −1 ⌽͑U͒D with U = DV is valid, where ⌽ is the recursion operator of the KdV hierarchy 27 ͑see also Sec. III͒.…”

Noncommutative Korteweg–de Vries and modified Korteweg–de Vries hierarchies via recursion methods

“…The choice of the recursion operator is inspired by related recursion operators admitted by the KdV and mKdV equations. 13,15,27,19,40 Actually the relation ⌿͑V͒ = D −1 ⌽͑U͒D with U = DV is valid, where ⌽ is the recursion operator of the KdV hierarchy 27 ͑see also Sec. III͒.…”

Noncommutative Korteweg–de Vries and modified Korteweg–de Vries hierarchies via recursion methods