2.1 Setup

Throughout, we will assume that $d,n>1$ since the theorem is clearly true if $d=1$ or $n=1$ . We will view the coefficients $c_u$ of f in (1.1) as coordinates on affine space $\mathbb {A}^{d+n \choose n}$ . To indicate the dependence of f on the choice of coefficients c, we will often write $f=f_c$ . Let K be the subset of all $u\in \mathbb {Z}_{\geq 0}^{n+1}$ such that $u_0+u_1=d$ , $u_i=0$ for $i>1$ , and $u_1<d$ . We then set

$$\begin{align*}W=V(\langle c_u \rangle_{u\in K})\subset \mathbb{A}^{d+n \choose n}. \end{align*}$$

The family of polynomials parameterized by W consists of all degree d forms such that the only monomial involving only $x_0$ and $x_1$ is $x_1^d$ .

We will be considering the map

$$ \begin{align*} \phi:\operatorname{\mathrm{GL}}(n+1)\times W&\to \mathbb{K}[x_0,\ldots,x_n]_d\\ (A,c)&\mapsto A.f_c, \end{align*} $$

where $A.f_c$ denotes the action of $A\in \operatorname {\mathrm {GL}}(n+1)$ on a polynomial $f_c=\sum c_ux^u$ via linear change of coordinates. We will be especially interested in the differential of $\phi $ at $(e,c)$ , where $e\in \operatorname {\mathrm {GL}}(n+1)$ is the identity. A straightforward computation shows that the image of the differential at $(e,c)$ is generated by

(2.1) $$ \begin{align} \kern2pt x^u\qquad\qquad\qquad\qquad\qquad\qquad\qquad u\notin K, \end{align} $$

(2.2) $$ \begin{align} &\frac{\partial f_c}{\partial x_i} \cdot x_j \qquad &0\leq i,j \leq n. \end{align} $$

The following lemma is the key to our proof.

Proof Consider the image of the differential of $\phi $ at $(e,c)$ . From (2.1), we obtain the span of all monomials of $\mathbb {K}[x_0,\ldots ,x_n]_d$ with the exceptions of the d monomials $x_0^d,x_0^{d-1}x_1,\ldots ,x_0x_1^{d-1}$ . From (2.2) with $i=1$ and $j=0$ , modulo (2.1), we additionally obtain the monomial $x_0x_1^{d-1}$ . We do not obtain anything new from (2.2) when $i=1$ and $j=1$ , when $i=0$ , or when $j>1$ .

It remains to consider the contributions to the image from (2.2) with $i>1$ and $j=0,1$ . For $2\leq i \leq n$ and $1\leq m\leq d-1$ , let $u(i,m)\in \mathbb {Z}^{n+1}$ be the exponent vector with $u_i=1$ , $u_0=m$ , $u_1=d-m-1$ . Modulo the span of (2.1) and $x_0x_1^{d-1}$ , from (2.2), we obtain

$$ \begin{align*} \frac{\partial f_c}{\partial x_i}\cdot x_0\equiv &c_{u(i,d-1)}x_0^d+c_{u(i,d-2)}x_0^{d-1}x_1+\cdots+c_{u(i,1)}x_0^2x_1^{d-2},\\ \frac{\partial f_c}{\partial x_i}\cdot x_1\equiv &\phantom{c_{u(i,d-1)}x_0^d+}c_{u(i,d-1)}x_0^{d-1}x_1+\cdots+c_{u(i,2)}x_0^2x_1^{d-2}. \end{align*} $$

Varying i from $2$ to n, we obtain $2n-2$ polynomials of degree d. The $(2n-2)\times (d-1)$ matrix of their coefficients has the form

$$\begin{align*}\left(\begin{array}{c c c c c} c_{u(2,d-1)} &c_{u(2,d-2)} &\ldots &c_{u(2,1)}\\ 0 &c_{u(2,d-1)} &\ldots &c_{u(2,2)}\\ c_{u(3,d-1)} &c_{u(3,d-2)} &\ldots &c_{u(3,1)}\\ 0 &c_{u(3,d-1)} &\ldots & c_{u(3,2)}\\ \vdots&\vdots&&\vdots\\ c_{u(n,d-1)}&c_{u(n,d-2)}&\ldots &c_{u(n,1)}\\ 0&c_{u(n,d-1)}&\ldots &c_{u(n,2)} \end{array} \right). \end{align*}$$

Since $c\in W$ is general, this matrix has full rank, that is, its rank is $\min \{d-1, 2n-2\}$ . Hence, the image of the differential of $\phi $ has codimension

$$\begin{align*}d-1-\min\{d-1,2n-2\}, \end{align*}$$

so the differential is surjective if and only if $d\leq 2n-1$ .

We now move on to prove the theorem.

2.2 Existence

We will first show that if $d\leq 2n-1$ , a general degree d hypersurface admits a toric Gröbner degeneration up to change of coordinates. As noted above, the family of polynomials parameterized by W consists of all degree d forms such that the only monomial involving only $x_0$ and $x_1$ is $x_1^d$ . Consider any $\omega \in \mathbb {R}^{n+1}$ such that

$$ \begin{align*} \omega_0>\omega_1>\omega_2>\cdots>\omega_n\qquad (d-1)\omega_0+\omega_2=d\omega_1. \end{align*} $$

For general $c\in W$ , the initial term of $f_{c}$ is

$$\begin{align*}ax_1^d+bx_0^{d-1}x_2 \end{align*}$$

for some $a,b\neq 0$ ; this is a prime binomial. Thus, we will be done with our first claim if we can show that the image of $\phi $ contains a non-empty open subset of $\mathbb {K}[x_0,\ldots ,x_n]_d$ .

To this end, we consider the image of the differential at $(e,c)$ for general $c\in W$ . By Lemma 2.1, we conclude that $\phi $ has surjective differential at $(e,c)$ for general $c\in W$ ; it follows that $\phi $ has surjective differential at a general point of $\operatorname {\mathrm {GL}}(n+1)\times W$ . Thus, the dimension of the image of $\phi $ is the dimension of $\mathbb {K}[x_0,\ldots ,x_n]_d$ , and the image of $\phi $ contains a non-empty open subset of $\mathbb {K}[x_0,\ldots ,x_n]_d$ .

2.3 Nonexistence

Assume now that $d>2n-1$ . We first give an overview of the proof strategy. There are only finitely many prime binomials g of degree d. Likewise, there are only finitely many linear orderings $\prec $ of the variable indices $0,\ldots ,n$ . We say that a weight vector $\omega $ is compatible with $\prec $ and g if whenever $i\prec j$ in the linear ordering, then $\omega _i\geq \omega _j$ , and the two monomials of g have the same weight with respect to $\omega $ .

For fixed g and linear ordering on the variables, we may consider the set S of all polynomials f in $\mathbb {K}[x_0,\ldots ,x_n]_d$ for which there exists a compatible weight vector $\omega \in \mathbb {R}^{n+1}$ such that initial term of f with respect to $\omega $ is g. We will show that up to permutation of the coordinates, this set S can be identified as a subfamily of W. By Lemma 2.1, the map $\phi $ has nowhere surjective differential. Thus, by generic smoothness, the dimension of the image of $\phi $ must be strictly less than the dimension of $\mathbb {K}[x_0,\ldots ,x_n]_d$ . It follows that there cannot be a Zariski-open subset of $\mathbb {K}[x_0,\ldots ,x_n]_d$ such that every hypersurface in this subset admits a toric Gröbner degeneration up to change of coordinates.

To complete the proof, we will fix a prime binomial $g=g'+g''$ of degree d and a linear ordering of the variables. Here, $g'$ and $g''$ are the two terms of g. After permuting the variables and appropriately adapting g, we may assume without loss of generality that the indices are ordered as $0\prec 1 \prec 2 \prec \cdots \prec n$ . The irreducibility of g implies that g involves at least three distinct variables, and no variable appears in both $g'$ and $g''$ . Let p be the smallest index such that $x_p$ appears in g; we denote the corresponding term by $g'$ . Let q be the smallest index such that $x_q$ appears in the term $g''$ .

If $g'$ only involves variables $x_i$ with indices $i<q$ , then any compatible term order $\omega $ must satisfy $\omega _p=\omega _q=\omega _j$ for all $p\leq j \leq q$ . Indeed, if not, the term $g''$ would necessarily have smaller weight. Without loss of generality, we may thus permute indices without changing the set of compatible weight vectors to also assume that $g'$ involves some $x_i$ with $i>q$ . For this, we are using that the irreducibility of g guarantees that at least one of $g'$ and $g''$ is not a dth power.

Consider the set S of polynomials $f_c$ such that there is a compatible weight $\omega $ for which $f_c$ has g as its initial term. We claim that S is a subset of the family parameterized by $W.$ Indeed, since $q>0$ , $g''$ has weight at most equal to the weight of $x_1^d$ . The monomials $x_0^d,x_0^{d-1}x_1,\ldots ,x_0x_1^{d-1}$ all have weight at least as big as the weight of $x_1^d$ , and are not scalar multiples of $g'$ or $g''$ . Hence, none of these monomials can appear in any element of S, and the claim follows.

The proof of the theorem now follows from the argument given above.