Proof. Consider the standard $ \mathbb {Z}^{p}$ -graded polynomial ring $R' = R[x_{n+1},\ldots ,x_{n+p}]$ with $\deg (x_{n+i}) = { \mathbf {e}}_i \in \mathbb {Z}^p$ , and notice that $\mathcal {C}(R/I;{ \mathbf {t}}) = \mathcal {C}(R'/IR';{ \mathbf {t}})$ . Thus, we assume that I is a relevant prime (i.e., $I \not \supset \bigoplus _{i_1\ge 1,\ldots , i_p\ge 1} {\left [R\right ]}_{(i_1,\ldots ,i_p)}$ ), and so $ \mathrm {MultiProj}(R/I) \neq \emptyset $ . We embed $X = \mathrm {MultiProj}(R/I)$ as a closed subscheme of a multiprojective space ${ \mathbb {P}}:={ \mathbb {P}}_{\mathbb {k}}^{m_1} \times _{\mathbb {k}} \cdots \times _{\mathbb {k}} { \mathbb {P}}_{\mathbb {k}}^{m_p}$ . From [Reference Castillo, Cid-Ruiz, Li, Montaño and Zhang3, Remark 2.9], we have that ${ \mathbf {n}} \in { \mathrm {supp}}(\mathcal {C}(R/I;{ \mathbf {t}}))$ if and only if $\deg _{ \mathbb {P}}^{{ \mathbf {m}}-{ \mathbf {n}}}(X)>0$ where ${ \mathbf {m}} - { \mathbf {n}}=(m_1-n_1,\ldots ,m_p-n_p)$ . Then, [Reference Castillo, Cid-Ruiz, Li, Montaño and Zhang3, Theorem A] implies that ${ \mathbf {n}} \in { \mathrm {supp}}(\mathcal {C}(R/I;{ \mathbf {t}}))$ if and only if $|{ \mathbf {n}}| = { \mathrm {codim}}(I)$ and $\sum _{j \in {\mathfrak {J}} }n_{j} \ge { \mathrm {codim}}\left (I_{({\mathfrak {J}})}\right )$ for each ${\mathfrak {J}} \subseteq [p]$ . Equivalently, we obtain that ${ \mathbf {n}} \in { \mathrm {supp}}(\mathcal {C}(R/I;{ \mathbf {t}}))$ if and only if $|{ \mathbf {n}}| = { \mathrm {codim}}(I)$ and

$$ \begin{align*} \sum_{j \in {\mathfrak{J}} }n_{j} \,\le\, {\mathrm{codim}}(I) - {\mathrm{codim}}\left(I_{([p] \setminus {\mathfrak{J}})}\right) \,=\, \sum_{j \in {\mathfrak{J}}} m_j + r([p] \setminus {\mathfrak{J}}) - r([p]) \end{align*} $$

for each ${\mathfrak {J}} \subseteq [p]$ , where $r : 2^{[p]} \rightarrow \mathbb {N}$ is the rank function $r({\mathfrak {J}}) := \dim \big ( \mathrm {MultiProj}\big (R_{({\mathfrak {J}})}/I_{({\mathfrak {J}})}\big )\big )$ (see [Reference Castillo, Cid-Ruiz, Li, Montaño and Zhang3, Proposition 5.1]). Finally, we can check that $s : 2^{[p]} \rightarrow \mathbb {N}$ with $s({\mathfrak {J}}) := \sum _{j \in {\mathfrak {J}}} m_j + r([p] \setminus {\mathfrak {J}}) - r([p])$ is a rank function (see, e.g., [Reference Schrijver20, §44.6f]), and so it follows that ${ \mathrm {supp}}(\mathcal {C}(R/I;{ \mathbf {t}}))$ is a polymatroid.

Proof. Notice that, if $\widetilde {F}_\bullet $ is a $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -graded free $\widetilde {R}$ -resolution of $\widetilde {R}/I$ with $\widetilde {F}_i = \bigoplus _{j} \widetilde {R}(-\mathbf {a}_{i,j},-\mathbf {b}_{i,j})$ , then there is a corresponding $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -graded free R-resolution $F_\bullet $ of $R/I$ with $F_i = \bigoplus _{j} R(-\mathbf {a}_{i,j},\mathbf {b}_{i,j})$ . By definition, this yields the equality of K-polynomials

$$ \begin{align*} \mathcal{K}(\widetilde{R}/I;{\mathbf{t}},{\mathbf{s}}) = \mathcal{K}(\widetilde{R}/I;t_1,\ldots,t_p,s_1,\ldots,s_p) = \mathcal{K}(R/I;t_1,\ldots,t_p,s_1^{-1},\ldots,s_p^{-1}) = \mathcal{K}(R/I;{\mathbf{t}},{\mathbf{s}}^{\mathbf{-1}}). \end{align*} $$

From [Reference Miller and Sturmfels18, Claim 8.54], we have $\mathcal {K}(R/I;\mathbf {1-t},\mathbf {1-s}) = \mathcal {C}(R/I;{ \mathbf {t}},{ \mathbf {s}}) + Q({ \mathbf {t}},{ \mathbf {s}})$ , where $Q({ \mathbf {t}},{ \mathbf {s}})$ is a polynomial with terms of degree at least ${ \mathrm {codim}}(I) + 1$ . Equivalently, we get $\mathcal {K}(R/I;{ \mathbf {t}},{ \mathbf {s}}) = \mathcal {C}(R/I;\mathbf {1-t},\mathbf {1-s}) + Q(\mathbf {1-t},\mathbf {1-s})$ . It then follows that

$$ \begin{align*} \mathcal{K}(\widetilde{R}/I;\mathbf{1-t},\mathbf{1-s}) = \mathcal{C}(R/I; t_1,\ldots,t_p,1-\tfrac{1}{1-s_1},\ldots,1-\tfrac{1}{1-s_p}) + Q(t_1,\ldots,t_p,1-\tfrac{1}{1-s_1},\ldots,1-\tfrac{1}{1-s_p}). \end{align*} $$

By expanding the right-hand side of the above equality, the result of the lemma is obtained.

Setup 4.1. Let $p \ge 1$ be a positive integer and $\mathbb {k}$ be a field. Let R and S be the polynomial rings $R=\mathbb {k}[{ \mathbf {x}}]$ and $S=\mathbb {k}[\mathbf {w}, \mathbf {z}]$ over the set of variables ${ \mathbf {x}} = \{x_{i,j}\}_{1\le i,j\le p}$ , $\mathbf {w} = \{w_{i,j}\}_{1\le i,j\le p}$ and $\mathbf {z} = \{z_{i,j}\}_{1\le i,j\le p}$ . We consider R and S as $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -graded rings by setting that

$$ \begin{align*} \deg(x_{i,j}) = {\mathbf{e}}_i \oplus {\mathbf{e}}_j, \quad \deg(w_{i,j}) = {\mathbf{e}}_i \oplus \mathbf{0} \quad \mathrm{and} \quad \deg(z_{i,j}) = \mathbf{0} \oplus {\mathbf{e}}_j, \end{align*} $$

where ${ \mathbf {e}}_i \in \mathbb {Z}^p$ denotes the i-th elementary vector and $\mathbf {0} \in \mathbb {Z}^p$ denotes the zero vector. We define the $\mathbb {k}$ -algebra homomorphism

$$ \begin{align*} \phi: R=\mathbb{k}[{\mathbf{x}}] \longrightarrow S = \mathbb{k}[\mathbf{w}, \mathbf{z}], \quad \phi(x_{i,j}) = w_{i,j}z_{i,j}. \end{align*} $$

For an R-homogeneous ideal $I \subset R$ , we say that the extension $\phi (I) S$ is the standardization of I, as $\phi (I) S$ is an S-homogeneous ideal in the standard multigraded polynomial ring S. Let ${ \mathbf {t}} = \{t_1,\ldots ,t_p\}$ and ${ \mathbf {s}} = \{s_1,\ldots ,s_p\}$ be variables indexing the $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -grading, where $t_i$ corresponds with ${ \mathbf {e}}_i \oplus \mathbf {0} \in \mathbb {Z}^p \oplus \mathbb {Z}^p$ and $s_i$ corresponds with $\mathbf {0} \oplus { \mathbf {e}}_i \in \mathbb {Z}^p \oplus \mathbb {Z}^p$ . Given a finitely generated graded R-module M and a finitely generated graded S-module N, by a slight abuse of notation, we consider both multidegrees $\mathcal {C}(M;{ \mathbf {t}},{ \mathbf {s}})$ and $\mathcal {C}(N;{ \mathbf {t}},{ \mathbf {s}})$ as elements of the same polynomial ring $ \mathbb {Z}[{ \mathbf {t}}, { \mathbf {s}}]= \mathbb {Z}[t_1,\ldots ,t_p,s_1,\ldots ,s_p]$ .

Proof. Let T be the polynomial ring $T=\mathbb {k}[{ \mathbf {x}},\mathbf {w},\mathbf {z}] \cong R \otimes _{\mathbb {k}} S$ with its natural $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -grading induced from the ones of R and S. We now think of R and S as subrings of T. Consider the quotient ring $T/IT$ , and notice that $\{x_{i,j} - w_{i,j}z_{i,j}\}_{1\le i,j \le p}$ is a regular sequence of homogeneous elements over $T/IT$ . We also have the following natural isomorphism

$$ \begin{align*} \frac{T}{IT + \left(\{x_{i,j} - w_{i,j}z_{i,j}\}_{1\le i,j \le p}\right)} \;\cong\; S/J. \end{align*} $$

As the natural inclusion $R \hookrightarrow T$ is a polynomial extension, we have that $\dim (T/IT) = \dim (R/I) + \dim (S) = \dim (R) + \dim (S) - { \mathrm {codim}}(I)$ and that $T/IT$ is Cohen–Macaulay when $R/I$ is. So, by cutting out with the regular sequence described above, we obtain that $ \dim (S/J) = \dim (T/IT) - \dim (R) = \dim (S) - { \mathrm {codim}}(I) $ and that $S/J$ is Cohen–Macaulay when $T/IT$ is. This completes the proofs of parts (i) and (iii).

Let $F_\bullet : \cdots \xrightarrow {f_2} F_1 \xrightarrow {f_1} F_0$ be a graded free R-resolution of $R/I$ . Since $\{x_{i,j} - w_{i,j}z_{i,j}\}_{1\le i,j \le p}$ is a regular sequence on both T and $T/IT$ , it follows that ${ \mathrm {Tor}}_k^T\left (T/IT, T/(\{x_{i,j} - w_{i,j}z_{i,j}\}_{1\le i,j \le p})\right ) = 0$ for all $k> 0$ , and so $G_\bullet = F_\bullet \otimes _R T/(\{x_{i,j} - w_{i,j}z_{i,j}\}_{1\le i,j \le p})$ provides (up to isomorphism) a graded free S-resolution of $S/J$ . The identification of $G_\bullet $ as a resolution of S-modules is the same as $\phi (F_\bullet )$ (more precisely, $G_\bullet $ has the same shiftings as $F_\bullet $ in the $( \mathbb {Z}^p \oplus \mathbb {Z}^p)$ -grading and the i-th differential matrix of $G_\bullet $ is given by the substitution $\phi (f_i)$ of $f_i$ ). Therefore, by definition, we obtain the equality $\mathcal {C}(R/I;{ \mathbf {t}},{ \mathbf {s}}) = \mathcal {C}(S/J;{ \mathbf {t}},{ \mathbf {s}})$ that shows part (ii).

To show part (iv) we can use Buchberger’s algorithm (see, e.g., [Reference Eisenbud6, Chapter 15]). Indeed, we can perform essentially the same steps of the algorithm in a set of generators of I and the corresponding set of generators for J.

Proof. Let $\mathcal {L} = \{ (i,j) \mid x_{i,j} \in I \}$ be the set of indices such that the corresponding variable belongs to I. We consider the polynomial rings $ R' = \mathbb {k}[x_{i,j} \mid (i,j) \not \in \mathcal {L}] \subset R $ and $ S' = \mathbb {k}[w_{i,j}, z_{i,j} \mid (i,j) \not \in \mathcal {L}] \subset S. $ Let $I' \subset R'$ be the (unique) ideal that satisfies the condition $I = I'R + \left (x_{i,j} \mid (i,j) \in \mathcal {L}\right )$ . By construction, we have that $x_{i,j} \not \in I'$ for all $x_{i,j} \in R'$ . Since $R/I \cong R'/I'$ , it follows that $I'$ is also a Cohen–Macaulay prime ideal.

Let $J' = \phi (I'R)S \cap S'$ . For any $w_{i,j}z_{i,j} \in S'$ , Proposition 4.2(i) and the fact that the corresponding $x_{i,j}$ does not belong to the prime $I'$ imply that

$$ \begin{align*} {\mathrm{codim}}(J'S+w_{i,j}z_{i,j}S) = {\mathrm{codim}}(I'R + x_{i,j}R) = {\mathrm{codim}}(I'R) + 1 = {\mathrm{codim}}(J'S) + 1. \end{align*} $$

By Proposition 4.2(iii), $S/J'S$ is Cohen–Macaulay, and so it necessarily follows that $w_{i,j}z_{i,j}$ is a nonzerodivisor over $S/J'S$ for all $w_{i,j}z_{i,j} \in S'$ . Consequently, we obtain that $S'/J'$ is a domain if and only if $\left (S'/J'\right )_{\prod w_{i,j}z_{i,j}}$ is a domain. Let $B = \mathbb {k}[w_{i,j},z_{i,j},z_{i,j}^{-1} \mid (i,j) \not \in \mathcal {L}]$ , and consider the automorphism given by

$$ \begin{align*} \psi : B \rightarrow B, \quad w_{i,j} \mapsto \frac{w_{i,j}}{z_{i,j}}, \quad z_{i,j} \mapsto {z_{i,j}}. \end{align*} $$

The ideal $\psi (J'B)$ coincides with the extension of $I'$ in B under the ring homomorphism $R' \rightarrow B, x_{i,j} \mapsto w_{i,j}$ , and so it follows that $\psi (J'B)$ and, consequently, $J'B$ are prime ideals. We then conclude that $J'$ is a prime ideal.

Since the variables $x_{i,j}$ with indices in $\mathcal {L}$ form a regular sequence over $R/I'R$ , we obtain the equation

(1) $$ \begin{align} \mathcal{C}(R/I;{\mathbf{t}}, {\mathbf{s}}) = \prod_{(i,j) \in \mathcal{L}} (t_i+s_j) \cdot \mathcal{C}(R/I'R;{\mathbf{t}}, {\mathbf{s}}) \end{align} $$

(see, e.g., [Reference Miller and Sturmfels18, Exercise 8.12]). To conclude the proof, it is now sufficient to show that the support of $\mathcal {C}(R/I'R;{ \mathbf {t}}, { \mathbf {s}})$ is a discrete polymatroid; indeed, we would obtain that the support of $\mathcal {C}(R/I;{ \mathbf {t}}, { \mathbf {s}})$ is a Minkowski sum of a finite number of discrete polymatroids which in turn is also a discrete polymatroid by [Reference Schrijver20, Corollary 46.2c]. Finally, this condition follows by applying Theorem 2.2 to the prime ideal $J'S$ and exploiting the equality $\mathcal {C}(R/I'R;{ \mathbf {t}}, { \mathbf {s}}) = \mathcal {C}(S/J'S;{ \mathbf {t}}, { \mathbf {s}})$ from Proposition 4.2(ii).

Proof of Theorem A.

As we already have all the necessary ingredients, the proof follows straightforwardly by combining Theorem 3.2, Lemma 3.3 and Theorem 4.3.

Proof. By Theorem 4.3, we know that the Newton polytope of $\mathcal {C}(R/I;{ \mathbf {t}}, { \mathbf {s}})$ is a base polymatroid polytope, and so, under the condition $\sum _{j \in [p]} r_j+ \sum _{j \in [p]} c_j = { \mathrm {codim}}(I)$ , all its defining inequalities are of the form

(2) $$ \begin{align} \sum_{j\in\mathfrak{J}_1}r_j+\sum_{j\in\mathfrak{J}_2}c_j \geq C({\mathfrak{J}}_1,{\mathfrak{J}}_2), \end{align} $$

for some constant $C({\mathfrak {J}}_1,{\mathfrak {J}}_2)$ that depends on the subsets ${\mathfrak {J}}_1,{\mathfrak {J}}_2 \subseteq [p]$ . We now determine $C({\mathfrak {J}}_1,{\mathfrak {J}}_2)$ .

We keep the same notation of the proof of Theorem 4.3, in particular, $I = I'R + \left (x_{i,j} \mid (i,j) \in \mathcal {L}\right )$ . Equation (1) decomposes the Newton polytope of $\mathcal {C}(R/I;{ \mathbf {t}}, { \mathbf {s}})$ as the Minkowski sum of the Newton polytopes of $\prod _{(i,j) \in \mathcal {L}} (t_i+s_j)$ and $\mathcal {C}(S/J'S;{ \mathbf {t}}, { \mathbf {s}})$ , both of which are also base polymatroid polytopes. So, we analyze the minimum of the sum in Equation (2) with the two contributions.

1. 1. $\textrm {Newton}(\prod _{(i,j) \in \mathcal {L}} (t_i+s_j))$ is determined by the equality $\sum _{j \in [p]} r_j+ \sum _{j \in [p]} c_j = |\mathcal {L}|$ and the inequalities $\sum _{j\in \mathfrak {J}_1}r_j+\sum _{j\in \mathfrak {J}_2}c_j \ge \big |\{(i,j)\in \mathcal {L} \mid i\in {\mathfrak {J}}_1 \mathrm { and } j\in {\mathfrak {J}}_2\}\big |$ .

2. 2. Due to Theorem 2.2, $\textrm {Newton}(\mathcal {C}(S/J'S;{ \mathbf {t}}, { \mathbf {s}}))$ is determined by the equality $\sum _{j \in [p]} r_j+ \sum _{j \in [p]} c_j = { \mathrm {codim}}(J'S)$ and the inequalities $\sum _{j\in \mathfrak {J}_1}r_j+\sum _{j\in \mathfrak {J}_2}c_j \ge { \mathrm {codim}} \big ({(J'S)}_{({\mathfrak {J}}_1,{\mathfrak {J}}_2)}\big )$ , where ${(J'S)}_{({\mathfrak {J}}_1,{\mathfrak {J}}_2)}$ is the contracted ideal ${(J'S)}_{({\mathfrak {J}}_1,{\mathfrak {J}}_2)} = J'S \cap S_{({\mathfrak {J}}_1,{\mathfrak {J}}_2)}$ .

Notice that Proposition 4.2(i) yields the equality

$$\begin{align*}{\mathrm{codim}} \big(I_{({\mathfrak{J}}_1,{\mathfrak{J}}_2)}\big) = {\mathrm{codim}} \big(J_{({\mathfrak{J}}_1,{\mathfrak{J}}_2)}\big) = {\mathrm{codim}} \big({(J'S)}_{({\mathfrak{J}}_1,{\mathfrak{J}}_2)}\big) + \big|\{(i,j)\in\mathcal{L} \mid i\in{\mathfrak{J}}_1 \textrm{ and } j\in{\mathfrak{J}}_2\}\big|. \end{align*}$$

Therefore, since we can split the value of $C({\mathfrak {J}}_1,{\mathfrak {J}}_2)$ in terms of the sum of the defining inequalities of the Newton polytopes of $\prod _{(i,j) \in \mathcal {L}} (t_i+s_j)$ and $\mathcal {C}(S/J'S;{ \mathbf {t}}, { \mathbf {s}})$ , it follows that $C({\mathfrak {J}}_1,{\mathfrak {J}}_2) = { \mathrm {codim}} \big (I_{({\mathfrak {J}}_1,{\mathfrak {J}}_2)}\big )$ . This concludes the proof of the theorem.