The Radical of the Kernel of a Certain Differential Operator and Applications to Locally Algebraic Derivations

Abstract

Let R be a commutative ring, A an R-algebra (not necessarily commutative) and V an R-subspace or R-submodule of A. By the radical of V we mean the set of all elements a∈ A such that am∈ V for all m 0. We derive (and show) some necessary conditions satisfied by the elements in the radicals of the kernel of some (partial) differential operators, such as all differential operators of commutative algebras; the differential operators P(D) of (noncommutative) A with certain conditions, where P(·) is a polynomial in n commutative free variables and D=(D1, D2, …, Dn) are either commuting locally finite R-derivations or commuting R-derivations of A such that for each 1 i n, A can be decomposed as a direct sum of the generalized eigen-subspaces of Di; etc. In particular, we show that the kernel of certain differential operators of A is a Mathieu subspace (see GIC, MS) of A. We then apply some results above to study R-derivations of A, which are locally algebraic or locally integral over R. In particular, we show that if R is an integral domain of characteristic zero and A is reduced and torsion-free as an R-module, then A has no nonzero locally algebraic R-derivations. We also show a formula for the determinant of a differential vandemonde matrix over a commutative algebra A. This formula not only provides some information for the elements in the radical of the kernel of all ordinary differential operators of A, but also is interesting on its own right.