Strength conditions, small subalgebras, and Stillman bounds in degree ≤ 4

Abstract

In [2], the authors prove Stillman's conjecture in all characteristics and all degrees by showing that, independent of the algebraically closed field K or the number of variables, n forms of degree at most d in a polynomial ring R over K are contained in a polynomial subalgebra of R generated by a regular sequence consisting of at most η\!B(n,d) forms of degree at most d: we refer to these informally as "small" subalgebras. Moreover, these forms can be chosen so that the ideal generated by any subset defines a ring satisfying the Serre condition Rη. A critical element in the proof is to show that there are functions η\!A(n,d) with the following property: in a graded n-dimensional K-vector subspace V of R spanned by forms of degree at most d, if no nonzero form in V is in an ideal generated by η\!A(n,d) forms of strictly lower degree (we call this a strength condition), then any homogeneous basis for V is an Rη sequence. The methods of AH2 are not constructive. In this paper, we use related but different ideas that emphasize the notion of a key function to obtain the functions η\!A(n,d) in degrees 2, 3, and 4 (in degree 4 we must restrict to characteristic not 2, 3). We give bounds in closed form for the key functions and the η\!A functions, and explicit recursions that determine the functions η\!B from the η\!A functions. In degree 2, we obtain an explicit value for η\!B(n,2) that gives the best known bound in Stillman's conjecture for quadrics when there is no restriction on n. In particular, for an ideal I generated by n quadrics, the projective dimension R/I is at most 2n+1(n - 2) + 4.