Proof. Clearly all coefficients of polynomials in the interior are positive. By, for example, [Reference Brändén and Huh7, Theorem 2.25, Lemma 2.5], the sufficiency (and equivalence) of (1) and (2) follows. Also, (2) and (3) are equivalent by homogeneity.

Suppose (2) fails for some f in the interior of $\mathbb {P}\underline {\mathrm {L}}^{d}_{n}$ , $\mathbf {y} \in \mathbb {S}^{n-d}_{\mathbf {1}}$ and $S\in \binom {[n]} {d-2}$ . Let $y_{k}=\min \{y_{i}\}$ and $y_{\ell }=\max \{y_{i}\}$ . Since the coefficients of f are positive, it follows that $\partial ^{S}f(t \mathbf {1} -\mathbf {y})=(t-a)^{2}$ , where $y_{k} < a <y_{\ell }$ . Let $f_{\epsilon } = (1+\epsilon )f-\epsilon w_{k}w_{\ell }\mathbf {w}^{S}$ . The discriminant of $\partial ^{S}f_{\epsilon }(t\mathbf {1} -\mathbf {y})$ is equal to $\epsilon ^{2}(y_{\ell }-y_{k})^{2}-4\epsilon (a-y_{k})(y_{\ell }-a)$ , which is negative for all $\epsilon>0$ sufficiently small. Hence, $f_{\epsilon }(t\mathbf {1} -\mathbf {y})$ has non-real zeros for such $\epsilon $ . This contradiction shows that (3) is necessary.

Proof. We may assume $d\geq 2$ . Let $|S|=d-2$ . The Hessian of $\partial ^{S} e_{d}=e_{2}$ , considered as a polynomial in $n-d+2$ variables, is $\mathbf {1}^{T} \mathbf {1}-I$ , where I is the identity matrix. This matrix has eigenvalues $-1, -1,\ldots , -1$ and $n-d+1$ .

Proof. Assume first that $\mathcal {L}=\tau $ is a transposition. It was proved in [Reference Brändén and Huh7, Corollary 3.9] that any operator of the form $(1-\theta )I + \theta \tau $ , where $0\leq \theta \leq 1$ , preserves the Lorentzian property. Since

$$ \begin{align*}e^{s\mathcal{L}}= \frac {e^{s}+e^{-s}} 2 I+ \frac {e^{s}-e^{-s}} 2 \tau, \end{align*} $$

we deduce $e^{s\mathcal {L}} : \underline {\mathrm {L}}^{d}_{n} \to \underline {\mathrm {L}}^{d}_{n}$ for all $s\geq 0$ .

Suppose $\mathcal {L}_{i} : \underline {\mathrm {H}}^{d}_{n} \to \underline {\mathrm {H}}^{d}_{n}$ are linear operators such that $e^{s\mathcal {L}_{i}} : \underline {\mathrm {L}}^{d}_{n} \to \underline {\mathrm {L}}^{d}_{n}$ for $i=1,2$ and all $s\geq 0$ . By the Trotter product formula [Reference Ethier and Kurtz8, page 33],

$$ \begin{align*}e^{s(\mathcal{L}_{1}+\mathcal{L}_{2})}= \lim_{k\to \infty} \left( e^{(s/k)\mathcal{L}_{1}} \circ e^{(s/k)\mathcal{L}_{2}}\right)^{k}. \end{align*} $$

Hence, $e^{s(\mathcal {L}_{1}+\mathcal {L}_{2})} : \underline {\mathrm {L}}^{d}_{n} \to \underline {\mathrm {L}}^{d}_{n}$ , for all $s\geq 0$ , since $\underline {\mathrm {L}}^{d}_{n}$ is closed. Iterating this proves the proposition.

Proof. By the open mapping theorem and Proposition 2.4, $T_{s}$ maps the interior of $\underline {\mathrm {L}}^{d}_{n}$ to itself for each $s\geq 0$ . Hence, it suffices to prove that if f is in $\mathbb {P}\underline {\mathrm {L}}^{d}_{n}$ , then $T_{s}(f)$ lies in the interior of $\mathbb {P}\underline {\mathrm {L}}^{d}_{n}$ for all $s>0$ sufficiently small.

All coefficients of $T_{s}(f)$ are positive for all $s>0$ and $f \in \mathbb {P}\underline {\mathrm {L}}^{d}_{n}$ . Let $f \in \mathbb {P}\underline {\mathrm {L}}^{d}_{n}$ and suppose $S \subset [n]$ has size $d-2$ and that $\mathbf {y} \in \mathbb {S}^{n-d}_{\mathbf {1}}$ . Denote by $\Delta _{S}(\mathbf {y};s)$ the discriminant of the degree $2$ polynomial

(2.2) $$ \begin{align} t \mapsto \partial^{S} T_{s}(f)(t \mathbf{1} - \mathbf{y}). \end{align} $$

From (2.1) it follows that $\Delta _{S}(\mathbf {y};s)$ defines an entire function in the (complex) variable s. Hence, either there is a positive number $\delta (\mathbf {y})$ for which $\Delta _{S}(\mathbf {y};s) \neq 0$ whenever $0<|s|<\delta (\mathbf {y})$ or $\Delta _{f}\!(\mathbf {y};s)$ is identically zero. The latter cannot happen since then, by letting $s \to \infty $ , it follows that the discriminant of the polynomial $t \mapsto e_{2}(t\mathbf {1} -\mathbf {y})$ is equal to zero, which contradicts the fact that $e_{2}(\mathbf {w})$ is in the interior of $\mathbb {P}\mathrm {L}^{2}_{n}$ . By compactness (of $\mathbb {S}^{n-d}_{\mathbf {1}}$ ) and Hurwitz’s theorem on the continuity of zeros, it follows that there is a uniform $\delta>0$ such that $\Delta _{S}(\mathbf {y};s) \neq 0$ whenever $0<|s|<\delta $ and $\mathbf {y} \in \mathbb {S}^{n-d}_{\mathbf {1}}$ and $S \subset [n]$ has size $d-2$ . Hence, $T_{s}(f)$ is in the interior of $\mathbb {P}\mathrm {L}^{d}_{n}$ for all $0<s<\delta $ .

Proof. Notice that $\underline {\mathrm {E}}_{\mathcal {A}}^{d}$ is the intersection of $\underline {\mathrm {E}}_{n}^{d}$ with an affine space, $f_{0}+U$ , where U is a linear subspace of $\operatorname {\mathrm {span}}\{f_{1},\ldots , f_{N}\}$ . We identify the affine linear space $\underline {\mathrm {E}}_{\mathcal {A}}^{d}$ with $\mathbb {R}^{M}$ , where $M=\dim (U)$ , equipped with the Euclidean norm, inherited by $\operatorname {\mathrm {span}}\{f_{1},\ldots , f_{N}\}$ ,

$$ \begin{align*}\| f \| = \sqrt{\sum_{i=1}^{N} x_{i}^{2}}, \ \ \ \ \ \mbox{ if } f = \sum_{i=1}^{N} x_{i}f_{i}. \end{align*} $$

Consider the map $F : \mathbb {R} \times \mathbb {R}^{M} \to \mathbb {R}^{M}$ defined by

$$ \begin{align*}F(s, f) = T_{s}(f). \end{align*} $$

Then

1. 1. the map F is continuous, by, for example, the explicit form (2.1),

2. 2. $F(0,f)=f$ and $F(s_{1}+s_{2}, f)=F(s_{1}, F(s_{2},f))$ , for all $f \in \mathbb {R}^{M}$ and $s_{1}, s_{2} \in \mathbb {R}$ ,

3. 3. $\|F(s,f)\| <\|f\|$ , for all $f \neq 0$ and $s>0$ , by Lemma 2.3.

Thus, F is a contractive flow, as defined in [Reference Galashin, Karp and Lam9]. By Lemma 2.5,

$$ \begin{align*}F(s, \mathbb{P}\underline{\mathrm{L}}^{d}_{\mathcal{A}}) \subset \mathrm{int}(\mathbb{P}\underline{\mathrm{L}}^{d}_{\mathcal{A}}) \ \ \text{for all} s>0, \end{align*} $$

where $\mathrm {int}$ denotes the interior. The theorem now follows from [Reference Galashin, Karp and Lam9, Lemma 2.3] and its proof.

Proof. Consider the variables $w_{ij}$ , $1\leq i \leq n$ and $1\leq j \leq \kappa _{j}$ , and let $\mathcal {A}=\{A_{1}, \ldots , A_{n}\}$ be the partition of $\{w_{ij}\}$ given by $A_{i}=\{ w_{ij} \mid 1\leq j \leq \kappa _{i}\}$ for $1 \leq i \leq n$ .

The polarisation operator $\Pi ^{\uparrow } : \mathrm {E}^{d}_{\kappa } \rightarrow \underline {\mathrm {E}}^{d}_{\mathcal {A}}$ is defined as follows. Let $f \in \mathrm {E}^{d}_{\kappa }$ . For all $i \in [n]$ and each monomial $w_{1}^{\alpha _{1}} \cdots w_{n}^{\alpha _{n}}$ in the expansion of f, replace $w_{i}^{\alpha _{i}}$ with

$$ \begin{align*}e_{\alpha_{i}}(w_{i1},\ldots, w_{i\kappa_{i}} )/ \binom {\kappa_{i}} {\alpha_{i}}. \end{align*} $$

The polarisation operator is a linear isomorphism with inverse $\Pi ^{\downarrow }$ defined by the change of variables $w_{ij} \to w_{i}$ . Also $\Pi ^{\uparrow }$ and $\Pi ^{\downarrow }$ preserve the Lorentzian property [Reference Brändén and Huh7, Proposition 3.1]. Hence, $\Pi ^{\uparrow }$ defines a homeomorphism between $\mathbb {P}\mathrm {L}^{d}_{\kappa }$ and $\mathbb {P}\underline {\mathrm {L}}_{\mathcal {A}}^{d}$ . The theorem now follows from Theorem 3.1.

Proof. For $\mathbf {y} \in \mathbb {R}^{n}$ , let $p(t)= \prod _{i=1}^{n} (t-y_{i})$ . Notice that

$$ \begin{align*}(n-d)!e_{d}(t\mathbf{1} -\mathbf{y}) = p^{(n-d)}(t),\end{align*} $$

the $(n-d)$ th derivative of $p(t)$ . Hence, all zeros of $e_{d}(t\mathbf {1} -\mathbf {y})$ are real. Moreover, if $\alpha $ is a zero of $e_{d}(t\mathbf {1} -\mathbf {y})$ of multiplicity $k \geq 2$ , then $\alpha $ is a zero of p of multiplicity $k+(n-d)$ . The lemma follows.

Proof. All coefficients of $f_{n}^{d}(\mathbf {w})$ are positive. We need to prove that the zeros of $f_{n}^{d}(t\mathbf {1} -\mathbf {y})$ are real and distinct whenever $\mathbf {y} \in \mathbb {R}^{n}$ is not parallel to $\mathbf {1}$ . This follows from Lemma 4.1, since

$$ \begin{align*}f_{n}^{d}(t\mathbf{1} -\mathbf{y})= e_{d}(t\mathbf{1} -\widetilde{\mathbf{y}})/\binom {nd} d, \mbox{ where } \widetilde{\mathbf{y}}=(y_{1},\ldots, y_{1}, \ldots, y_{n}, \ldots, y_{n}).\\[-42pt] \end{align*} $$

Proof. The proof is a modification of the proof of Theorem 3.1.

It was proved in [Reference Borcea, Brändén and Liggett6, Proposition 5.1] that SEP preserves stability on multiaffine polynomials. Also, in [Reference Borcea and Brändén4, Proposition 3.4] it was proved that the polarisation operator $\Pi ^{\uparrow }$ preserves stability. For $s \in \mathbb {R}$ , define $\widehat {T}_{s} : \mathrm {E}_{n}^{d} \to \mathrm {E}_{n}^{d}$ by $\widehat {T}_{s}= \Pi ^{\downarrow } \circ T_{s} \circ \Pi ^{\uparrow }$ , where $T_{s}$ is the SEP on $\underline {\mathrm {E}}_{nd}^{d}$ , with rates $q_{\tau } = 1/ \binom {nd} 2$ for all transpositions $\tau $ . By the discussion in Section 3, it follows that $\widehat {T}_{s}$ is a contractive flow, which contracts the space to the point $f_{n}^{d}(\mathbf {w})$ in its interior (Lemma 4.2). To finish the proof, it remains to prove that for each fixed $f \in \mathbb {P}\mathrm {S}^{d}_{n}$ , there is a $\delta>0$ such that $\widehat {T}_{s}(f)$ is in the interior of $\mathbb {P}\mathrm {S}^{d}_{n}$ for all $0<s<\delta $ .

Let $f \in \mathbb {P}\mathrm {S}^{d}_{n}$ and $\mathbf {y} \in \mathbb {S}^{n-2}_{\mathbf {1}}$ . Denote by $\Delta _{f}\!(\mathbf {y};s)$ the discriminant of the polynomial $ t \mapsto \widehat {T}_{s}(f)(t\mathbf {1}-\mathbf {y})$ . From (2.1) it follows that $\Delta _{f}\!(\mathbf {y};s)$ defines an entire function in the (complex) variable s. Hence, either there is a positive number $\delta (\mathbf {y})$ for which $\Delta _{f}\!(\mathbf {y};s) \neq 0$ whenever $0<|s|<\delta (\mathbf {y})$ or $\Delta _{f}\!(\mathbf {y};s)$ is identically zero. The latter cannot happen since then, by letting $s \to \infty $ , it follows that the discriminant of the polynomial $t \mapsto f_{n}^{d}(t\mathbf {1} -\mathbf {y})$ is equal to zero, which contradicts the fact that $f_{n}^{d}(\mathbf {w})$ is in the interior of $\mathbb {P}\mathrm {S}^{d}_{n}$ . By compactness (of $\mathbb {S}^{n-2}_{\mathbf {1}}$ ) and Hurwitz’s theorem on the continuity of zeros, it follows that there is a uniform $\delta>0$ such that $\Delta _{f}\!(\mathbf {y};s) \neq 0$ whenever $0<|s|<\delta $ and $\mathbf {y} \in \mathbb {S}^{n-2}_{\mathbf {1}}$ . Hence, $\widehat {T}_{s}(f)$ is in the interior of $\mathbb {P}\mathrm {S}^{d}_{n}$ for all $0<s<\delta $ .