Continuous closure, axes closure, and natural closure

Abstract

Let R be a reduced affine C-algebra, with corresponding affine algebraic set X. Let C(X) be the ring of continuous (Euclidean topology) C-valued functions on X. Brenner defined the continuous closure I cont of an ideal I as I C(X) R. He also introduced an algebraic notion of axes closure I ax that always contains I cont, and asked whether they coincide. We extend the notion of axes closure to general Noetherian rings, defining f ∈ I ax if its image is in IS for every homomorphism R S, where S is a one-dimensional complete seminormal local ring. We also introduce the natural closure I of I. One of many characterizations is I = I + \f ∈ R: ∃ n >0 with fn ∈ In+1\. We show that I ⊂eq I ax, and that when continuous closure is defined, I ⊂eq I cont ⊂eq I ax. Under mild hypotheses on the ring, we show that I= I ax when I is primary to a maximal ideal, and that if I has no embedded primes, then I = I if and only if I = I ax, so that I cont agrees as well. We deduce that in the polynomial ring C[x1, …, xn], if f = 0 at all points where all of the ∂ f ∂ xi are 0, then f ∈ ( ∂ f ∂ x1, \, …, \, ∂ f ∂ xn)R. We characterize I cont for monomial ideals in polynomial rings over C, but we show that the inequalities I ⊂ I cont and I cont ⊂ I ax can be strict for monomial ideals even in dimension 3. Thus, I cont and I ax need not agree, although we prove they are equal in C[x1, x2].