Lie algebras of conservation laws of variational partial differential equations

Abstract

We establish a version of the first Noether Theorem, according to which the (equivalence classes of) conserved quantities of given Euler-Lagrange equations in several independent variables are in one-to-one correspondence with the (equivalence classes of) vector fields satisfying an appropriate pair of geometric conditions, namely: (a) they preserve the class of vector fields tangent to holonomic submanifolds of a jet space; (b) they leave invariant the action, from which the Euler-Lagrange equations are derived, modulo terms identically vanishing along holonomic submanifolds. Such correspondence between symmetries and conservation laws is built on an explicit linear map fA from the vector fields satisfying (a) and (b) into the conserved differential operators, and not into their divergences as it occurs in other proofs of Noether Theorem. This map fA is not new: it is the map determined by contracting symmetries with a form of Poincare'-Cartan type A and it is essentially the same considered for instance in a paper by Kupershmidt. There it was shown that fA determines a bijection between symmetries and conservation laws in a special form. Here we show that, if appropriate regularity assumptions are satisfied, any conservation law is equivalent to one that belongs to the image of fA, proving that the corresponding induced map FA between equivalence classes of symmetries and equivalence classes of conservation laws is actually a bijection. All results are given coordinate-free formulations and rely just on basic differential geometric properties of finite-dimensional manifolds.