Proof. Since $\mathcal {F}_{n}$ is isomorphic to $\mathcal {F}_{S_{n}}$ , Theorem 3.6 shows that $\mathcal {F}_{n}$ has a strong P-moduli space which is a coproduct of countably many affine k-varieties. From [Reference Tonini and YasudaTY23, Lemma 8.7 and Theorem 8.9], $\mathcal {F}_{n}^{\circ }$ also has a strong P-moduli space which is a coproduct of countably many affine k-varieties. From [Reference Wood and YasudaWY15], the discriminant exponent function $\mathbf {d}\colon \mathcal {F}_{n}\to \mathbb {Z}_{\ge 0}$ , which is identified with the Artin conductor $\mathbf {a}\colon \mathcal {F}_{S_{n}}\to \mathbb {Z}_{\ge 0}$ , is a special case of v-function $\mathbf {v}\colon \mathcal {F}_{S_{n}}\to \mathbb {Z}_{\ge 0}$ . From [Reference Tonini and YasudaTY23, Theorem 9.8], $\mathbf {d}$ is a locally constructible function. Hence, the property “ $\mathbf {d}=m$ ” is locally constructible. From [Reference Tonini and YasudaTY23, Theorem 8.9], $\mathcal {F}_{n}^{(m)}$ also has a P-moduli spaces which is a coproduct of countably many affine k-varieties.

Proof. In the situation of the proposition, we have

For i with $p\nmid (n-i)$ , we have

$$ \begin{align*} n\operatorname{\mathrm{ord}}\left((n-i)y_{i}\varpi^{n-i-1}\right) & \equiv n-i-1\quad\mod n\mathbb{Z}. \end{align*} $$

In particular, for distinct i’s, these values are different to one another. Therefore,

$$\begin{align*}n\operatorname{\mathrm{ord}} f'_y(\varpi)=\min\left\{ n-i-1+n\operatorname{\mathrm{ord}} y_{i}\mid0\le i<n,\,p\nmid(n-i)\right\}. \end{align*}$$

Moreover, if , the minimum is attained at i with $m+i+1\in n\mathbb {Z}$ . This proves the proposition.

Proof. The jet scheme $\operatorname {\mathrm {J}}_{l}V$ is the affine space $\mathbb {A}_{k}^{n(l+1)}$ with the coordinates $y_{i,j}$ , $1\le i\le n$ , $0\le j\le l$ . The subset $\mathfrak {Eis}_{l}^{(m)}$ of it is defined by

$$\begin{align*}\begin{cases} y_{i,0}=0 & (1\le i\le n),\\ y_{n,1}\ne0,\\ y_{i,j}=0 & \left(i<n,\,p\nmid(n-i),\,j<\left\lceil \frac{c+i}{n}\right\rceil \right),\\ y_{i,\frac{c+i}{n}}\ne0 & \left(i<n,\,p\nmid(n-i),\,c+i\in n\mathbb{Z}\right), \end{cases} \end{align*}$$

which shows that $\mathfrak {Eis}_{l}^{(m)}$ is a locally closed subset. The last two conditions can be rephrased as:

$$\begin{align*}\begin{cases} y_{i,j}=0 & \left(i<n,\,p\nmid(n-i),\,c+i\notin n\mathbb{Z},\,j\le\left\lfloor \frac{c+i}{n}\right\rfloor \right)\\ y_{i,j}=0 & \left(i<n,\,p\nmid(n-i),\,c+i\in n\mathbb{Z},\,j<\left\lfloor \frac{c+i}{n}\right\rfloor \right)\\ y_{i,\frac{c+i}{n}}\ne0 & \left(i<n,\,p\nmid(n-i),\,c+i\in n\mathbb{Z}\right). \end{cases} \end{align*}$$

Thus, we have

$$\begin{align*}\mathfrak{Eis}_{l}^{(m)}\cong\mathbb{G}_{m}^{2}\times\mathbb{A}_{k}^{nl-s-1}, \end{align*}$$

where

$$\begin{align*}s=\sum_{\substack{1\le i<n\\ p\nmid(n-i) } }\left\lfloor \frac{c+i}{n}\right\rfloor. \end{align*}$$

Let us write $n=pn'$ . From Hermite’s identity (for example, see [Reference Savchev and AndreescuST03, Chapter 12]), we have

$$ \begin{align*} s & =\sum_{i=1}^{n-1}\left\lfloor \frac{c}{n}+\frac{i}{n}\right\rfloor -\sum_{i=1}^{n'-1}\left\lfloor \frac{c}{n}+\frac{i}{n'}\right\rfloor \\ & =\left\lfloor n\frac{c}{n}\right\rfloor -\left\lfloor n'\frac{c}{n}\right\rfloor \\ & =c-\left\lfloor \frac{c}{p}\right\rfloor.\\[-41pt] \end{align*} $$

Proof. Since the leading coefficient $F_{m}(y_{i,j})$ of $F(y_{1},\dots ,y_{n})$ is an invertible element of R, is invertible and is étale.

Proof. The proof is also similar to the one of [Reference FontaineFon85, Proposition 1.5]. Let us write and let $f(X)$ be the minimal polynomial of $\alpha $ over , which is of degree . We embed L and E into an algebraic closure $\Omega $ of and denote the extension of the valuation $\operatorname {\mathrm {ord}}$ to $\Omega $ again by $\operatorname {\mathrm {ord}}$ . Let $\beta \in \mathcal {O}_{E}$ be a lift of $\eta (\alpha )$ . Then $\operatorname {\mathrm {ord}}\,f(\beta )\ge l$ . Let $\alpha =\alpha _{1},,\dots ,\alpha _{n}\in \Omega $ be the conjugates of $\alpha $ . Since $f(\beta )=\prod _{i=1}^{n}(\beta -\alpha _{i})$ , we have

(4.2) $$ \begin{align} \sup_{i}\operatorname{\mathrm{ord}}(\beta-\alpha_{i})\ge\frac{\operatorname{\mathrm{ord}}(f(\beta))}{n}\ge\frac{l}{n}>\frac{\mathbf{d}_{L}}{n}. \end{align} $$

Recall that the discriminant of is the ideal generated by $\prod _{i\ne j}(\alpha _{j}-\alpha _{i})$ . Suppose that $\operatorname {\mathrm {ord}}(\alpha _{1}-\alpha _{2})=\sup _{i\ne j}\operatorname {\mathrm {ord}}(\alpha _{i}-\alpha _{j})$ . If $\sigma _{i}$ , $1\le i\le n$ , are -automorphisms of $\Omega $ with $\sigma _{i}(\alpha )=\alpha _{i}$ . Then,

(4.3) $$ \begin{align} \mathbf{d}_{L}\ge\sum_{i\ne j}\operatorname{\mathrm{ord}}(\alpha_{i}-\alpha_{j})\ge\sum_{i=1}^{n}\operatorname{\mathrm{ord}}(\sigma_{i}(\alpha_{1})-\sigma_{i}(\alpha_{2}))\ge n\operatorname{\mathrm{ord}}(\alpha_{1}-\alpha_{2}). \end{align} $$

Combining (4.2) and (4.3) gives

$$\begin{align*}\sup_{i}\operatorname{\mathrm{ord}}(\beta-\alpha_{i})>\sup_{i\ne j}\operatorname{\mathrm{ord}}(\alpha_{i}-\alpha_{j}). \end{align*}$$

From Krasner’s lemma [Reference LangLan94, II, S2, Proposition3], for i with $\operatorname {\mathrm {ord}}(\beta -\alpha _{i})=\sup _{i}\operatorname {\mathrm {ord}}(\beta -\alpha _{i})$ , we have . The composite map

is a -embedding.

Proof. From the last proposition, there exists a -embedding $L\to L'$ . Because of their degrees, it is an isomorphism.

Proof. For a geometric point $y\in \mathfrak {Eis}^{(m)}(K)$ , the field extension has discriminant exponent m. Since

if $y,y'\in \mathfrak {Eis}^{(m)}(K)$ map to the same point of $\mathfrak {Eis}_{l}^{(m)}(K)$ for $l\ge m$ , then $A_{y}$ and $A_{y'}$ are isomorphic over . This proves the corollary.

Proof. We first note that from Remark 3.10, the assertion is independent of the choice of the P-moduli space $\Delta _{n}^{\circ }$ of the functor $\mathcal {F}_{n}^{\circ }$ . For an algebraically closed field K, every totally ramified extension is associated to some Eisenstein polynomial. This shows that

$$\begin{align*}\operatorname{\mathrm{Im}}(\psi^{(m)})=\operatorname{\mathrm{Im}}(\psi_{l}^{(m)})=\Delta_{n}^{(m)}. \end{align*}$$

Since the P-morphism $\psi _{l}^{(m)}$ is represented by a morphism $Y\to \Delta _{n}^{\circ }$ of k-schemes with Y a k-variety, its image is quasicompact and constructible.

Proof. Let and $b\in K^{*}=\mathbb {G}_{m}(K)$ . Let

$$\begin{align*}y':=by=(by_{1},b^{2}y_{2},\dots,b^{n}y_{n}). \end{align*}$$

We have an isomorphism $A_{y}\to A_{y'},\,x\mapsto b^{-1}x$ . This shows that $\psi ^{(m)}$ is $\mathbb {G}_{m}$ -invariant. Similarly for $\psi _{l}^{(m)}$ .

Proof. Since the proof is a little long and technical, we divide it into several steps.

A setup. By base change, we may assume that $K=k$ and that they are algebraically closed. Then, the point $A\in \Delta _{n}^{(m)}(k)$ is identified with an étale -algebra of degree n. Let $Z=\operatorname {\mathrm {Spec}} R$ be an affine smooth irreducible curve over k with a distinguished closed point $0\in \operatorname {\mathrm {Spec}} R$ and let $y\colon Z\to \mathfrak {Eis}_{l}^{(m)}$ be a k-morphism such that an open dense subset $Z^{\circ }\subset Z$ maps into $\psi _{l}^{-1}(A)$ . We will show that the distinguished point $0$ also maps into $\psi _{l}^{-1}(A)$ , which implies the proposition. Let be the algebra corresponding to y. Each point $z\in Z(k)$ induces a homomorphism , which in turn induces an algebra . For $z\in Z^{\circ }(k)$ , we have $A_{y,z}\cong A$ . Our goal is to show that $A_{y,0}\cong A$ .

Strategy. Our strategy to achieve this goal is as follows. For a group G of a special form, we construct some G-torsor which factors through $\operatorname {\mathrm {Spec}} A_{y}$ . We show that for each point $z\in Z(k)$ , the “fiber” $B_{y,z}$ is isomorphic to $(\widetilde {A_{y,z}})^{v}$ for some $v\in \mathbb {Z}_{>0}$ , where $\widetilde {A_{y,z}}$ denotes a Galois closure of . For such a group G, we have a fine moduli stack $\widetilde {\Delta }_{G}$ of G-torsors over and have the morphism $Z\to \widetilde {\Delta }_{G}$ corresponding to the above G-torsor. We will see that the image of the map $Z(k)\to \widetilde {\Delta }_{G}(k)/{\cong }$ is finite and hence the map is constant. This implies the desired conclusion.

Construction of  $ {B_{y}}$ . We begin to construct a G-torsor as above. Let and be the $S_{n}$ -torsors corresponding to the degree-n étale algebras and , respectively (for example, see [Reference SerreSer58, Section 1.5]). If we identify $S_{n-1}$ with the stabilizer of $1$ for the action $S_{n}\curvearrowright \{1,\dots ,n\}$ , then $(C_{y})^{S_{n-1}}=A_{y}$ and $(C_{y,0})^{S_{n-1}}=A_{y,0}$ . Let $\operatorname {\mathrm {Spec}} B_{y,0}'\subset \operatorname {\mathrm {Spec}} C_{y,0}$ be a connected component and let $G\subset S_{n}$ be its stabilizer so that is a G-torsor and is a Galois closure of . Since the residue field k of is algebraically closed, G coincides with its inertia group (often denoted by $G_{0}$ ). From [Reference SerreSer79, p. 68, Corollary 4], $G=G_{0}$ is the semidirect product $H\rtimes C$ of a p-group H and a cyclic group C of order coprime to the characteristic of k. If $G'$ denotes the stabilizer of 1 for the action $G\curvearrowright \{1,\dots ,n\}$ , then $A_{y,0}=(B_{y,0}')^{G'}$ .

Let $u\in A_{y}$ be the image of x by the map

and let $\overline {u}$ be the image of u in $A_{y,0}$ . Then, and . Let . Then $B_{y}'$ is a finitely generated torsion-free -module. Note that is a Noetherian domain of dimension 2. Moreover, is excellent [Reference ValabregaVal75] and [Reference MatsumuraMat87, Theorem 19.5]. It follows that the localization is an excellent Dedekind domain. Since $B_{y}'$ is a torsion-free -module and $B_{y,0}'$ is a free -module of rank $|G|$ , $B_{y}'$ is a locally free -module of rank $|G|$ . Moreover, the subring $B_{y}'\subset C_{y}$ is stable under the G-action.

From [Reference GrothendieckGro65, Scholie 7.8.3], the ring $B_{y}'$ is excellent. Therefore, the normalization $B_{y}$ of $B_{y}'$ is finitely generated as a $B_{y}'$ -module as well as an -module. By a similar reasoning as above, $B_{y}$ is a locally free -module of rank $|G|$ . We also see that $B_{y}$ is a locally free $A_{y}$ -module of rank $|G'|=|G|/n$ . We have natural morphisms of Dedekind schemes

(4.4)

Morphisms $\alpha ,\beta ,\gamma $ as well as their compositions are flat. The morphism $\alpha \circ \beta $ is G-invariant and the morphism $\beta $ is $G'$ -invariant. We know that $\alpha $ and $\alpha \circ \beta \circ \gamma $ are étale. From [Reference GrothendieckGro67, Proposition 17.7.7], $\alpha \circ \beta $ is étale. From [Reference GrothendieckGro67, Proposition 17.3.4], $\beta $ is also étale.

Proving that  is a G -torsor. We now claim that the G-action on $\operatorname {\mathrm {Spec}} B_{y}$ is free. Each element $g\in G\setminus \{1\}$ acts nontrivially on $B_{y,0}'$ and hence also on $B_{y}'$ and $B_{y}$ . If the G-action on $\operatorname {\mathrm {Spec}} B_{y}$ is not free, then for some $g\in G\setminus \{1\}$ , the quotient morphism $\operatorname {\mathrm {Spec}} B_{y}\to (\operatorname {\mathrm {Spec}} B_{y})/\langle g\rangle $ is ramified. But, this is impossible due to [Reference GrothendieckGro67, Proposition 17.3.3(v)] and the fact that the morphism is étale and factors through $(\operatorname {\mathrm {Spec}} B_{y})/\langle g\rangle $ . This shows the claim. We have shown that is an étale finite morphism of degree $|G|$ and G-invariant for a free G-action on $\operatorname {\mathrm {Spec}} B_{y}$ . We conclude that this is a G-torsor. By the same argument, we also see that $\operatorname {\mathrm {Spec}} B_{y}\to \operatorname {\mathrm {Spec}} A_{y}$ is a $G'$ -torsor. In summary, we have shown that some compositions of morphisms in (4.4) are torsors for groups displayed in the following diagram:

“Fibers” of ${B_{y}}$ are powers of Galois closures. For a point $z\in Z(k)$ , base changing (4.4) with , we get a sequence of finite étale morphisms

If denotes a Galois closure of , then $C_{y,z}\cong (\widetilde {A_{y,z}})^{u}$ for some $u\in \mathbb {Z}_{>0}$ . Since is a G-torsor, we can write $B_{y,z}\cong D^{v}$ for some Galois extension . Then, D is an intermediate field of $\widetilde {A_{y,z}}/A_{y,z}$ such that is Galois, which shows that $D=\widetilde {A_{y,z}}$ and $B_{y,z}\cong (\widetilde {A_{y,z}})^{v}$ .

Completing the proof by using a moduli stack. Since G is the semidirect product $H\rtimes C$ of a p-group H and a tame cyclic group C, we can use the moduli stack $\widetilde {\Delta }_{G}$ of G-torsors over constructed in [Reference Tonini and YasudaTY20] (denoted by $\Delta _{G}$ in the cited paper). The stack $\widetilde {\Delta }_{G}$ is written as the inductive limit of Deligne–Mumford stacks $\mathcal {X}_{n}$ , $n\in \mathbb {Z}_{\ge 0}$ of finite type, where transition morphisms $\mathcal {X}_{n}\to \mathcal {X}_{n+1}$ are representable and universally injective. In particular, we have

Since Z is quasicompact, the morphism $Z\to \widetilde {\Delta }_{G}$ corresponding to the G-torsor factors through a morphism $Z\to \mathcal {X}_{n}$ for some n. Recall that for $z\in Z^{\circ }(k)$ , we have an -isomorphism $A_{y,z}\cong A$ . Therefore, for $z\in Z^{\circ }(k)$ , $\widetilde {A_{y,z}}\cong \widetilde {A},$ where $\widetilde {A}$ is a Galois closure of . It follows that for $z\in Z^{\circ }(k)$ , $B_{y,z}\cong (\widetilde {A})^{v}$ as a -algebra. There are at most finitely many G-torsor structures which can be given to the morphism . It follows that the image of the map $Z^{\circ }(k)\to \mathcal {X}_{n}(k)/{\cong }$ is a finite set. Since $(Z\setminus Z^{\circ })(k)$ is a finite set, the image of the map $Z(k)\to \mathcal {X}_{n}(k)/{\cong }$ is also finite. Since Z is irreducible, we conclude that the map $Z(k)\to \mathcal {X}_{n}(k)/{\cong }$ is constant. Hence, the G-torsors , $z\in Z(k)$ are isomorphic to one another. It follows that étale -algebras $A_{y,z}=(B_{y,z})^{G'}$ , $z\in Z(k)$ are isomorphic to one another, and hence all of them are isomorphic to A. In particular, $A_{y,0}\cong A$ as desired.

Proof. The first assertion follows from construction. For a field extension $L/K$ , let . As a base change of map (5.1), we get a surjection

$$\begin{align*}\{\text{uniformizers of } {A_{L}}\}\to\{y\in\mathfrak{Eis}^{(m)}(L)\mid A_{y}\cong A_{L}\},\,\varpi'\mapsto f_{\varpi'}. \end{align*}$$

This shows $\phi _{\infty }(\mathfrak {Uf}_{A})=\psi ^{-1}(A)$ . We get

$$\begin{align*}\phi_{l}(\mathfrak{Uf}_{A,l})=\phi_{l}(\pi_{l}(\mathfrak{Uf}_{A}))=\pi_{l}(\phi_{\infty}(\mathfrak{Uf}_{A}))=\pi_{l}(\psi^{-1}(A))=\psi_{l}^{-1}(A), \end{align*}$$

where the last equality follows from Corollary 4.11.

Proof. The first assertion follows from the fact that the automorphism of induced by $\sigma \in H$ is linear and degree-preserving. To show the second assertion, it is enough to show that $S_{i}$ are H-invariant. For $\sigma ,\sigma '\in H$ , we have

$$ \begin{align*} \sum_{b=0}^{n-1}\sigma(w_{b})\sigma'(\varpi^{b}) & =\sum_{b=0}^{n-1}\sum_{a=0}^{n-1}c_{ab}^{\sigma}w_{a}\sigma'(\varpi^{b})\\ & =\sum_{a=0}^{n-1}w_{a}\sum_{b=0}^{n-1}c_{ab}^{\sigma}\sigma'(\varpi^{b})\\ & =\sum_{a=0}^{n-1}w_{a}(\sigma'\sigma)(\varpi^{a}). \end{align*} $$

Since the $s_{i}$ are symmetric polynomials and the sequences $(\sigma \sigma _{1})(\varpi ^{a}),\dots ,(\sigma \sigma _{m})(\varpi ^{a})$ and $\sigma _{1}(\varpi ^{a}),\dots ,\sigma _{m}(\varpi ^{a})$ are permutations of each other, we have

$$ \begin{align*} S_{i}(\sigma(w_{0}),\dots,\sigma(w_{n-1})) & =s_{i}\left(\sum_{a=0}^{n-1}\sigma(w_{a})\sigma_{1}(\varpi^{a}),\dots,\sum_{a=0}^{n-1}\sigma(w_{a})\sigma_{n}(\varpi^{a})\right)\\ & =s_{i}\left(\sum_{a=0}^{n-1}w_{a}(\sigma\sigma_{1})(\varpi^{a}),\dots,\sum_{a=0}^{n-1}w_{a}(\sigma\sigma_{n})(\varpi^{a})\right)\\ & =S_{i}(w_{0},\dots,w_{n-1}). \end{align*} $$

Thus $\phi $ is H-invariant.

Proof. For a uniformizer $\varpi '$ , the associated Eisenstein polynomial is also written as $f_{\varpi '}=\prod _{i=1}^{n}(x-\sigma _{i}(\varpi '))$ . Therefore, if $f_{\varpi '}=f_{\varpi "}$ , then $\varpi '$ and $\varpi "$ are conjugate and $\varpi "=\sigma (\varpi ')$ for some $\sigma \in H$ . Thus $\mathfrak {Uf}_{A}(L)/H\to \psi ^{-1}(A)(L)$ is injective. The surjectivity follows from Lemma 5.2.

Proof. The left equality is obvious. The right equality follows from the fact that the discriminant is the norm of the different and a formula for valuations of norms (for example, [Reference NeukirchNeu99, Chapter II, (4.8) and Chapter III, (2.9)]). The Galois closure $\tilde {A}$ is obtained as the composite of all conjugates of A in an algebraic closure of . This shows . Indeed Toyama [Reference TôyamaTôy55] proved the corresponding result for the composite of two number fields. The same argument applies to the case of local fields and the generalization to the composite of an arbitrary number of local fields is straightforward. It follows that .

Proof. By taking a base change, we may assume that K is algebraically closed, in particular, perfect. Then, we can apply the theory of ramification groups explained in [Reference SerreSer79, Chapter IV]; we follow the notation from this reference. From [Reference SerreSer79, p. 64, Proposition 4], for $1\ne g\in G$ , . Let $a=em$ and let $G_{a}$ be the a-th ramification group (lower numbering) consisting of g with $i_{G}(g)\ge a+1$ . Using Lemma 5.5, we see that if $g\ne 1$ , then $i_{G}(g)\le a$ and hence $g\notin G_{a}$ . Thus, we conclude that $G_{a}=1$ . Let be the Herbrand function so that , where the right-hand side is a higher ramification group with the upper numbering. From [Reference SerreSer79, p.64, Proposition 4 and p. 74, Lemma 3], we have

Thus $G^{2m}=1$ . From [Reference DeligneDel84, Proposition A.6.1] and [Reference SerreSer79, p.61, Lemma 1], if $\sigma \colon A\hookrightarrow \tilde {A}$ is a -embedding different from the chosen embedding $A\hookrightarrow \widetilde {A}$ , which we denote by $\sigma _{0}$ , and if $\varpi '\in \mathcal {O}_{A}$ is a uniformizer, then

$$ \begin{align*} 2\cdot\operatorname{\mathrm{ord}}(\sigma(\varpi')-\varpi') & \le\sum_{\tau\ne\sigma_{0}}\operatorname{\mathrm{ord}}(\tau(\varpi')-\varpi')+\sup_{\tau\ne\sigma_{0}}\operatorname{\mathrm{ord}}(\tau(\varpi')-\varpi')\\ & <2m+1. \end{align*} $$

and hence $\operatorname {\mathrm {ord}}(\sigma (\varpi ')-\varpi ')<m+1$ . In particular, for $1\ne h\in H$ , if $l\ge m$ , then

$$\begin{align*}h(\varpi')\ne\varpi'\quad\mod t^{l+1}. \end{align*}$$

This shows the lemma.

Proof. Since $S_{i}$ is the composite of $s_{i}(x_{1},\dots ,x_{n})$ and $x_{j}=\sum _{a}w_{a}\sigma _{j}(\varpi ^{a})$ , the above Jacobian matrix can be written as

(6.1) $$ \begin{align} \left.\frac{\partial(s_{1},\dots,s_{n})}{\partial(x_{1},\dots,x_{n})}\right|{}_{x_{i}=\sum_{a=0}^{n-1}w_{a}\sigma_{i}(\varpi^{a})}\times\frac{\partial\left(\sum_{a=0}^{n-1}w_{a}\sigma_{1}(\varpi^{a}),\dots,\sum_{a=0}^{n-1}w_{a}\sigma_{n}(\varpi^{a})\right)}{\partial(w_{0},\dots,w_{n-1})}. \end{align} $$

Concerning the first factor, as was proved in [Reference SerreSer78, p. 1036], we have

$$\begin{align*}\det\frac{\partial(s_{1},\dots,s_{n})}{\partial(x_{1},\dots,x_{n})}=\prod_{i<j}(x_{i}-x_{j}). \end{align*}$$

For $\gamma =(\gamma _{0},\dots ,\gamma _{n-1})\in \mathfrak {Uf}_{A}$ , substituting $\gamma _{a}$ for $w_{a}$ in

$$\begin{align*}\left.\left(\prod_{i<j}(x_{i}-x_{j})\right)\right|{}_{x_{i}=\sum_{a=0}^{n-1}w_{a}\sigma_{i}(\varpi^{a})}, \end{align*}$$

we get

$$\begin{align*}\prod_{i<j}(\sigma_{i}(\varpi_{\gamma})-\sigma_{j}(\varpi_{\gamma})). \end{align*}$$

From [Reference KeuneKeu23, the proof of Proposition 1.29], its square is the discriminant of $1,\varpi _{\gamma },\dots ,\varpi _{\gamma }^{n-1}$ .

On the other hand, concerning the second factor of (6.1), we have

$$\begin{align*}\frac{\partial\left(\sum_{a=0}^{n-1}w_{a}\sigma_{1}(\varpi^{a}),\dots,\sum_{a=0}^{n-1}w_{a}\sigma_{n}(\varpi^{a})\right)}{\partial(w_{0},\dots,w_{n-1})}=(\sigma_{i}(\varpi^{a}))_{i,a}. \end{align*}$$

The discriminant of with respect to the basis $1,\varpi ,\dots ,\varpi ^{n-1}$ is the square of $\det (\sigma _{i}(\varpi ^{a}))_{i,a}$ [Reference KeuneKeu23, Proposition 1.28]. We have showed that the determinants of the two factors in (6.1) both have order $m/2$ , which shows $\operatorname {\mathrm {ord}}_{\mathcal {J}}(\gamma )=m$ .

Proof. Suppose that two points $b_{l},b_{l}'\in \mathfrak {Uf}_{A,l}(L)$ map to the same point $a_{l}\in \mathfrak {Eis}_{l}^{(m)}(L)$ . Let $b,b'\in \mathfrak {Uf}_{A}(L)$ be lifts of $b_{l},b_{l}'$ respectively and let $a:=\phi _{\infty }(b)\in \mathfrak {Eis}^{(m)}(L)$ . Then, from [Reference Chambert-Loir, Nicaise and SebagCLNS18, Chapter 5, Proposition 3.1.7], there exists $c\in \mathfrak {Uf}_{A}$ such that $\phi _{\infty }(c)=a$ and the images $c_{l-m},b^{\prime }_{l-m}\in \mathfrak {Uf}_{A,l-m}$ of $c,b'$ are the same. Note that the constant $c_{V}$ appearing in the cited result is taken to be $1$ in our situation, since V is smooth. The condition that $\phi _{\infty }(c)=\phi _{\infty }(b)=a$ implies that c is in the H-orbit of b. Therefore $H(c_{l-m})=H(b_{l-m})=H(b_{l-m}')$ . This shows the lemma.

Proof. By base change, we may suppose that $K=k$ and they are algebraically closed. Moreover, it suffices to consider fibers over closed points. In the rest of this proof, all points that we consider are closed. For $a_{l}\in \psi _{l}^{-1}(A)$ , the fiber $(\overline {\phi _{l}})^{-1}(a_{l})$ of $\overline {\phi _{l}}\colon \mathfrak {Uf}_{A,l}/H\to \mathfrak {Eis}_{l}^{(m)}$ over $a_{l}$ is contained in the fiber $(\pi _{l-m}^{l})^{-1}(\overline {b_{l-m}})$ of the truncation map $\pi _{l-m}^{l}\colon \mathfrak {Uf}_{A,l}/H\to \mathfrak {Uf}_{A,l-m}/H$ over a point $\overline {b_{l-m}}\in \mathfrak {Uf}_{A,l-m}/H$ . Let $b_{l-m}\in \mathfrak {Uf}_{A,l-m}$ be a lift of $\overline {b_{l-m}}$ . From Lemma 5.6, since $l-m\ge m$ , the H-action on $\mathfrak {Uf}_{A,l-m}$ is free. In particular, for $h\in H\setminus \{1\}$ , $h(b_{l-m})\ne b_{l-m}$ , which shows that for two distinct points of $\pi _{l-m}^{-1}(b_{l-m})$ , the H-action cannot send one point to the other. From Lemma 5.4, the restriction of $\phi _{\infty }$ to $\pi _{l-m}^{-1}(b_{l-m})$ is injective. The freeness of the H-action on $\mathfrak {Uf}_{A,l-m}$ also shows that the map $(\pi _{l-m}^{l})^{-1}(b_{l-m})\to (\pi _{l-m}^{l})^{-1}(\overline {b_{l-m}})$ is an isomorphism. From [Reference Chambert-Loir, Nicaise and SebagCLNS18, Chapter 5, Theorem 3.2.2.c], $(\pi _{l-m}^{l})^{-1}(b_{l-m})\to \mathfrak {Eis}_{l}^{(m)}$ is a piecewise $\mathbb {A}^{m}$ -bundle over its image and so is $(\pi _{l-m}^{l})^{-1}(\overline {b_{l-m}})\to \mathfrak {Eis}_{l}^{(m)}$ . Since $(\overline {\phi _{l}})^{-1}(a_{l})\subset (\pi _{l-m}^{l})^{-1}(\overline {b_{l-m}})$ , we conclude that $(\overline {\phi _{l}})^{-1}(a_{l})\cong \mathbb {A}_{k}^{m}$ .

Proof. Let $L/k$ be the algebraically closed field such that y is an L-point. For $\lambda \in \mathbb {G}_{m}(L)$ , if we write , we have

$$\begin{align*}\lambda\cdot y=(\lambda y_{1},\dots,\lambda^{n}y_{n}). \end{align*}$$

Thus, if $y_{i}\ne 0$ for some i, then $\operatorname {\mathrm {Stab}}(y)$ is contained $\mu _{i}$ , the group of i-th roots of $1$ . From Proposition 4.4, there exists $i\in \{1,\dots ,n-1\}$ such that $p\nmid i$ and $y_{i}\ne 0$ , which proves the lemma.

Proof. Let $y\in \psi _{l}^{-1}(A)(L)$ be a geometric point and let $\overline {y}$ be its image in $(\psi _{l}^{-1}(A)/\mathbb {G}_{m,K})(L)$ . Let C be the stabilizer at y for the $\mathbb {G}_{m,K}$ -action on $\psi _{l}^{-1}(A)$ , which is a finite and tame cyclic group from Lemma 6.6. From [Reference Abramovich and VistoliAV02, Lemma 2.3.3], the fiber of $\mathfrak {Uf}_{A,l}/(H\times \mathbb {G}_{m,K})\to \psi _{l}^{-1}(A)/\mathbb {G}_{m,K}$ over $\overline {y}$ is the quotient of the fiber of $\mathfrak {Uf}_{A,l}/H\to \psi _{l}^{-1}(A)$ over y by the action of C. The corollary follows from Lemma 6.5.

Proof. Again by a base change argument, we may assume that $K=k$ and they are algebraically closed and consider only closed points. Let $\mathfrak {m}_{A}$ be the maximal ideal of A and let $\mathfrak {C}_{n(l+1)}\subset \mathfrak {Uf}_{A,l}$ be the subvariety corresponding to elements of

$$\begin{align*}\mathcal{O}_{A}/t^{l+1}\mathcal{O}_{A}=\mathcal{O}_{A}/\mathfrak{m}_{A}^{n(l+1)} \end{align*}$$

that are equal to the chosen uniformizer $\varpi $ modulo $\mathfrak {m}_{A}^{2}$ . For $2\le i\le n(l+1)$ , let $\mathfrak {C}_{i}$ be the variety corresponding to the images of such elements in $\mathcal {O}_{A}/\mathfrak {m}_{A}^{i}$ . As a K-variety, $\mathfrak {C}_{i}$ is isomorphic to $\mathbb {A}_{K}^{i-2}$ . We define a (lower-numbering) filtration $H_{*}$ of H in the way which is standard if is a Galois extension: for $i\ge 0$ ,

$$\begin{align*}H_{i}:=\operatorname{\mathrm{Ker}}(H\to\operatorname{\mathrm{Aut}}(\mathcal{O}_{A}/\mathfrak{m}_{A}^{i+1})). \end{align*}$$

For a uniformizer $\varpi \in A$ , the map $g\mapsto g(\varpi )/\varpi $ defines an injective homomorphism $H_{i}/H_{i+1}\to U^{i}/U^{i+1}$ . From [Reference SerreSer61, Section 1.6], $U^{0}/U^{1}\cong \mathbb {G}_{m}$ and for $i\ge 1$ , $U^{i}/U^{i+1}\cong \mathbb {G}_{a}$ . Therefore $H_{0}/H_{1}$ is a tame cyclic group and $H_{i}/H_{i+1}$ , $i\ge 1$ are elementary abelian p-groups. Similarly, for $i\ge 1$ , we can have an embedding $H_{i}/H_{i+1}\to \mathfrak {m}_{L}^{i+1}/\mathfrak {m}_{L}^{i+2}$ by $g\mapsto g(\varpi )-\varpi $ .

We claim that the composite morphism

$$\begin{align*}\mathfrak{C}_{n(l+1)}\hookrightarrow\mathfrak{Uf}_{A,l}\to\mathfrak{Uf}_{A,l}/\mathbb{G}_{m} \end{align*}$$

is an isomorphism. Indeed, the morphism is clearly a universal homeomorphism. To show that it is an isomorphism, it is enough to show that it is étale. We have the $\mathbb {G}_{m}$ -equivariant morphism $\mathfrak {Uf}_{A,l}\to \mathbb {G}_{m}$ corresponding to the map sending a uniformizer $\varpi '$ to $\lambda \in k^{*}$ if $\varpi '=\lambda \varpi $ modulo $\mathfrak {m}_{A}^{2}$ . This is a smooth morphism and $\mathfrak {C}_{n(l+1)}$ is the fiber over $1\in \mathbb {G}_{m}$ of this morphism. This shows that $\mathfrak {C}_{n(l+1)}$ intersects with each $\mathbb {G}_{m}$ -orbit transversally, which implies that $\mathfrak {C}_{n(l+1)}\to \mathfrak {Uf}_{A,l}/\mathbb {G}_{m,k}$ is étale. We have proved the claim.

We see that $H(\mathfrak {C}_{n(l+1)})\subset \mathfrak {Uf}_{A,l}$ consists of $|H/H_{1}|$ connected components, each of which is isomorphic to $\mathfrak {C}_{n(l+1)}$ . The stabilizer of the component $\mathfrak {C}_{n(l+1)}\subset H(\mathfrak {C}_{n(l+1)})$ is $H_{1}$ . Therefore $\mathfrak {Uf}_{A,l}/(H\times \mathbb {G}_{m})\cong \mathfrak {C}_{n(l+1)}/H_{1}$ . We claim that for every $j\ge 1$ and every i with $2\le i\le n(l+1)$ , the map $\mathfrak {C}_{i}/H_{j}\to \mathfrak {C}_{i-1}/H_{j}$ is an $\mathbb {A}^{1}$ -bundle. To see this, we first note that $\mathfrak {C}_{i}\to \mathfrak {C}_{i-1}$ is a bundle with fiber $\mathfrak {m}_{L}^{i-1}/\mathfrak {m}_{L}^{i}=\mathbb {G}_{a}$ . If $j\ge i-1$ , then the $H_{j}$ -actions on $\mathfrak {C}_{i}$ and $\mathfrak {C}_{i-1}$ are trivial and the claim follows. If $j=i-2$ , then the map of the claim has fibers isomorphic to

$$\begin{align*}(\mathfrak{m}_{L}^{i-1}/\mathfrak{m}_{L}^{i})/(H_{i-2}/H_{i-1})\cong\mathbb{G}_{a}. \end{align*}$$

The last isomorphism follows from [Reference MilneMil17, Corollary 14.56]. For $j<i-2$ , the map of the claim is identified with

$$\begin{align*}(\mathfrak{C}_{i}/H_{i-2})/(H_{j}/H_{i-2})\to\mathfrak{C}_{i-1}/(H_{j}/H_{i-2}). \end{align*}$$

The claim now holds since the action of $H_{j}/H_{i-2}$ on $\mathfrak {C}_{i-1}$ is free. We have proved the claim.

Thus we obtain a tower of $\mathbb {A}^{1}$ -bundles

$$\begin{align*}\mathfrak{Uf}_{A,l}/(H\times\mathbb{G}_{m})\cong\mathfrak{C}_{n(l+1)}/H_{1}\to\mathfrak{C}_{n(l+1)-1}/H_{1}\to\cdots\to\mathfrak{C}_{2}/H_{1}=\mathrm{pt}. \end{align*}$$

This shows the lemma.

Proof. We first note that from Proposition 4.15, $\psi _{l}^{-1}(A)\subset \mathfrak {Eis}_{l}^{(m)}\otimes _{k}K$ is a closed subset, which is also $\mathbb {G}_{m,K}$ -invariant. Therefore, $\psi _{l}^{-1}(A)/\mathbb {G}_{m,K}\subset (\mathfrak {Eis}_{l}^{(m)}\otimes _{k}K)/\mathbb {G}_{m,K}$ is also a closed subset (for example, see [Reference Newstead, Brambila-Paz, García-Prada, Ramanan and BradlowNew09, Theorem 1.1]). From Corollary 6.7 and Lemma 6.8, $\psi _{l}^{-1}(A)/\mathbb {G}_{m,K}$ is a weak $\mathbb {A}_{K}^{n(l+1)-2-m}$ .

Proof. (1) By assumption, $\Gamma \cap \mathrm {pr}_{X}^{-1}(x)$ is a closed subset of $\mathrm {pr}_{X}^{-1}(x)$ . Let C be its closure in $Y\times X$ , which is contained in $\mathrm {pr}_{X}^{-1}(\overline {\{x\}})$ . Since $C\cap \mathrm {pr}_{X}^{-1}(x)=\Gamma \cap \mathrm {pr}_{X}^{-1}(x)$ , the symmetric difference $C\triangle \Gamma $ is a constructible subset whose image in X does not contain x. Let $Z:=\overline {\{x\}}\cap \mathrm {pr}_{X}(C\triangle \Gamma )$ . This is a constructible subset of $\overline {\{x\}}$ which does not contain x. Let $U_{x}:=\overline {\{x\}}\setminus \overline {Z}$ , which is an open dense subset of $\overline {\{x\}}$ . By construction, we have $C\cap \mathrm {pr}_{X}^{-1}(U_{x})=\Gamma \cap \mathrm {pr}_{X}^{-1}(U_{x})$ , which is a closed subset of $\mathrm {pr}_{X}^{-1}(U_{x})$ .

(2) We show this in the stronger form such that for every j, $W_{j}:=\bigsqcup _{i=j}^{l}X_{i}$ is a closed subset of X. We construct $X_{i}$ ’s inductively as follows. We put $X_{1}$ to be $U_{\eta }$ for the generic point $\eta $ of an irreducible component of $W_{1}=B$ having the maximal dimension. Suppose that we have constructed $X_{1},\dots ,X_{j-1}$ and let $W_{j}=X\setminus \bigcup _{i=1}^{j-1}X_{i}$ . We take the generic point $\xi $ of an irreducible component of $W_{j}$ having the maximal dimension. We put $X_{j}:=U_{\xi }\cap W_{j}$ and $W_{j+1}:=W_{j}\setminus X_{j}$ . We then have

$$\begin{align*}(\dim W_{i},\nu(W_{i}))>(\dim W_{i+1},\nu(W_{i+1})), \end{align*}$$

where pairs are ordered lexicographically and $\nu (-)$ means the number of irreducible components of maximal dimension. The procedure ends after finitely many steps and gives a desired decomposition of X.

Proof. From Proposition 4.15, the P-morphism $h\colon \mathfrak {Eis}_{l}^{(m)}/\mathbb {G}_{m}\to \Delta _{n}^{(m)}$ satisfies the assumption of Lemma 6.10. Therefore, if $\Gamma $ denotes its graph, then there exists a decomposition $\Delta _{n}^{(m)}=\bigsqcup _{i=1}^{l}X_{i}$ into locally closed subsets $X_{i}$ such that for each i, $\mathrm {pr}_{\Delta _{n}^{(m)}}^{-1}(X_{i})\cap \Gamma $ is a locally closed subset. Giving these locally closed subsets the reduced scheme structures, let us consider the coproducts $X:=\coprod _{i=1}^{l}X_{i}$ and $Y:=\coprod _{i=1}^{l}(\mathrm {pr}_{\Delta _{n}^{(m)}}^{-1}(X_{i})\cap \Gamma )$ . The natural morphism $f\colon Y\to X$ induces the P-morphism $h\colon \mathfrak {Eis}_{l}^{(m)}/\mathbb {G}_{m}\to \Delta _{n}^{(m)}$ . From construction, the morphism

$$\begin{align*}\mathrm{pr}_{\Delta_{n}^{(m)}}^{-1}(X_{i})\cap\Gamma\to h^{-1}(X_{i}) \end{align*}$$

is a universal homeomorphism. From Lemma 6.9, this is a very weak $\mathbb {A}^{n(l+1)-2-m}$ -bundle.

Proof. Take a morphism $Y\to X$ as in Corollary 6.12. We have the following equalities in $K_{0}^{\heartsuit }(\mathbf {Var}/k)$ :

$$\begin{align*}[\mathfrak{Eis}_{l}^{(m)}/\mathbb{G}_{m}]=[Y]=[X]\mathbb{L}^{n(l+1)-2-m}=[\Delta_{n}^{(m)}]\mathbb{L}^{n(l+1)-2-m}.\\[-37pt] \end{align*}$$

Proof. In $\widehat {\mathcal {M}}_{k}^{\heartsuit }$ ,

$$ \begin{align*} [\Delta_{n}^{(m)}]\mathbb{L}^{-m} & =[\mathfrak{Eis}_{l}^{(m)}/\mathbb{G}_{m}]\mathbb{L}^{-n(l+1)+2}\\ & =\mu(\mathfrak{Eis}^{(m)}/\mathbb{G}_{m})\mathbb{L}^{-n+2}. \end{align*} $$

It follows that

$$ \begin{align*} \int_{\Delta_{n}^{\circ}}\mathbb{L}^{-\mathbf{d}} & =\mathbb{L}^{-n+2}\sum_{m}\mu(\mathfrak{Eis}^{(m)}/\mathbb{G}_{m})\\ & =\mathbb{L}^{-n+2}\mu(\mathfrak{Eis}/\mathbb{G}_{m})\\ & =\mathbb{L}^{-n+1}\in\widehat{\mathcal{M}}_{k}^{\heartsuit}.\\[-39pt] \end{align*} $$

Proof. The natural P-morphism

$$\begin{align*}\coprod_{l=1}^{n}\coprod_{(q_{i})\in P(n,l)}\prod_{i=1}^{l}\Delta_{q_{i}}^{\circ}\to\Delta_{n},\,(A_{i})_{1\le i\le l}\mapsto\prod_{i=1}^{l}A_{i} \end{align*}$$

is geometrically bijective. Moreover, we have

$$\begin{align*}\mathbf{d}(\prod_{i}A_{i})=\sum_{i}\mathbf{d}(A_{i}). \end{align*}$$

Thus

$$\begin{align*}\int_{\prod_{i=1}^{l}\Delta_{q_{i}}^{\circ}}\mathbb{L}^{-\mathbf{d}}=\prod_{i=1}^{l}\int_{\Delta_{q_{i}}^{\circ}}\mathbb{L}^{-\mathbf{d}}=\prod_{i=1}^{l}\mathbb{L}^{-q_{i}+1}=\mathbb{L}^{-n+l} \end{align*}$$

and

$$ \begin{align*} \int_{\Delta_{n}}\mathbb{L}^{-\mathbf{d}} & =\sum_{l=1}^{n}\sum_{(q_{i})\in P(n,l)}\int_{\prod_{i=1}^{l}\Delta_{q_{i}}^{\circ}}\mathbb{L}^{-\mathbf{d}}\\ & =\sum_{l=1}^{n}\sum_{(q_{i})\in P(n,l)}\mathbb{L}^{-n+l}\\ & =\sum_{l=1}^{n}P(n,l)\mathbb{L}^{-n+l}\\ & =\sum_{j=0}^{n-1}P(n,n-j)\mathbb{L}^{-j}.\\[-44pt] \end{align*} $$

Proof. (1) For an algebraically closed field K, $\Delta _{n}^{(0)}(K)$ is a singleton corresponding to the trivial étale algebra , which shows the assertion.

(2) If corresponds to an Eisenstein polynomial $x^{n}+y_{1}x^{n-1}+\cdots +y_{n}$ , then from (4.1), we have

$$\begin{align*}\mathbf{d}_{A_{y}}=n\min_{0\le i\le n}\operatorname{\mathrm{ord}}\left(\sum_{i=0}^{n}(n-i)y_{i}\varpi^{n-i-1}\right). \end{align*}$$

If $p\nmid n$ , then the minimum on the right side is attained by $\operatorname {\mathrm {ord}} n\varpi ^{n-1}=(n-1)/n$ and $\mathbf {d}_{A_{y}}=n-1$ , which shows (a). (The case (a) follows also from the proof of (3).) Suppose $p\mid n$ and is a totally ramified extension of degree n and discriminant exponent m. From Proposition 4.4, for some i with $p\nmid i$ and $0\le i\le n-1$ , we have

$$\begin{align*}m=n-i-1+n\operatorname{\mathrm{ord}} y_{i}. \end{align*}$$

It follows that

$$\begin{align*}m-n+1=n\operatorname{\mathrm{ord}} y_{i}-i>0 \end{align*}$$

and

$$\begin{align*}p\nmid(m-n+1). \end{align*}$$

This shows (b) and (c).

(3) Let K be an algebraically closed field and let be an extension of degree n. Let $\widetilde {A}$ be its Galois closure with Galois group G. We may identify G with a transitive subgroup of $S_{n}$ . Moreover, G is isomorphic to the semidirect product $H\rtimes C$ of a p-group H and a tame cyclic subgroup C if $p>0$ and isomorphic to a cyclic group if $p=0$ . We claim that if $p>0$ , then $H=1$ . To show this by contradiction, suppose that $H\ne 1$ . Since $p\nmid n$ and H is a p-group, the H-action on $\{1,\dots ,n\}$ has at least one fixed point, say 1. Since G is transitive, there exists $g\in G$ such that $g(1)$ is not fixed by H. Then, $g^{-1}Hg\ne H$ , which contradicts the fact that H is a normal subgroup of G. We have proved the claim. Then, $G=C$ is the cyclic subgroup of $S_{n}$ generated by a cyclic permutation of an n-cycle. In particular, the stabilizer $\operatorname {\mathrm {Stab}}(1)$ of $1\in \{1,\dots ,n\}$ is trivial and $A=\widetilde {A}^{G}=\widetilde {A}$ . We conclude that is a cyclic Galois extension. As is well-known, A is isomorphic to . Hence $\Delta _{n}^{(m-1)}(K)$ is a singleton, which shows the assertion.

(4) We put $c:=m-n+1$ . From Lemma 7.3, we have

$$ \begin{align*} [\Delta_{n}^{(m)}] & =[\mathfrak{Eis}_{l}^{(m)}/\mathbb{G}_{m}]\mathbb{L}^{-nl+c+1}\in K_{0}^{\heartsuit}(\mathbf{Var}_{k}). \end{align*} $$

Since the $\mathbb {G}_{m}$ -torsor $\mathfrak {Eis}_{l}^{(m)}\to \mathfrak {Eis}_{l}^{(m)}/\mathbb {G}_{m}$ is Zariski locally trivial thanks to Hilbert’s Theorem 90, we have

$$\begin{align*}[\mathfrak{Eis}_{l}^{(m)}/\mathbb{G}_{m}]=(\mathbb{L}-1)^{-1}[\mathfrak{Eis}_{l}^{(m)}] \end{align*}$$

in $\mathcal {M}_{k}^{\heartsuit }[(\mathbb {L}-1)^{-1}]$ . From Corollary 4.6,

$$\begin{align*}[\mathfrak{Eis}_{l}^{(m)}]=(\mathbb{L}-1)^{2}\mathbb{L}^{nl-c+\lfloor c/p\rfloor-1}. \end{align*}$$

Combining these equalities, we get

$$ \begin{align*} [\Delta_{n}^{(m)}] & =(\mathbb{L}-1)^{-1}\left((\mathbb{L}-1)^{2}\mathbb{L}^{(nl-c+\lfloor c/p\rfloor-1)}\right)\mathbb{L}^{-nl+c+1}\\ & =(\mathbb{L}-1)\mathbb{L}^{\lfloor c/p\rfloor} \end{align*} $$

in $\mathcal {M}_{k}^{\heartsuit }[(\mathbb {L}-1)^{-1}]$ . Since $\mathbb {L}-1$ is invertible in $\widehat {\mathcal {M}}_{k}^{\heartsuit }$ , we have a natural homomorphism $\mathcal {M}_{k}^{\heartsuit }[(\mathbb {L}-1)^{-1}]\to \widehat {\mathcal {M}}_{k}^{\heartsuit }$ . Thus, the same equality holds also in $\widehat {\mathcal {M}}_{k}^{\heartsuit }$ .