2.1 Carrier algebras

Carrier algebras for $\mathfrak {g}$ are constructed as follows. For a nonzero nilpotent $e\in \mathfrak {g}_1$ choose an $\mathfrak {sl}_2$ -triple $(h,e,f)$ where $h\in \mathfrak {g}_0$ and $f\in \mathfrak {g}_{-1}$ ; this means $[h,e]=2e$ , $[h,f]=-2f$ and $[e,f]=h$ . Let $\mathfrak {t}_0$ be a maximal toral subalgebra of the centraliser of $(h,e,f)$ in $\mathfrak {g}_0$ and define $\mathfrak {t}=\mathbb {C} h\oplus \mathfrak {t}_0$ . Equivalently, $\mathfrak {t}$ is a maximal toral subalgebra of the normaliser of $\mathbb {C} e$ in $\mathfrak {g}_0$ (see [Reference Dietrich, de Graaf, Ruggeri and Trigiante13, Lemma 30]), where $\mathbb {C} e$ denotes the $\mathbb {C}$ -span of e. Now let $\lambda \colon \mathfrak {t}\to \mathbb {C}$ such that $[t,e]=\lambda (t)e$ for all $t\in \mathfrak {t}$ , and define the $\mathbb {Z}$ -graded algebra $\mathfrak {g}(\mathfrak {t},e)$ by

(2.1) $$ \begin{align} \mathfrak{g}(\mathfrak{t},e)=\bigoplus_{k\in\mathbb{Z}} \mathfrak{g}(\mathfrak{t},e)_k\quad\text{with }\mathfrak{g}(\mathfrak{t},e)_k=\{x\in \mathfrak{g}_{k} : [t,x]=k\lambda(t)x\text{ for all }t\in\mathfrak{t}\}. \end{align} $$

The derived subalgebra of $\mathfrak {g}(\mathfrak {t},e)$ is the carrier algebra of e, denoted by

$$ \begin{align*} \mathfrak{c}(e)=[\mathfrak{g}(\mathfrak{t},e),\mathfrak{g}(\mathfrak{t},e)]. \end{align*} $$

It is $\mathbb {Z}$ -graded with the induced grading; note that $e\in \mathfrak {c}(e)_1$ . This carrier algebra of e is unique up to conjugacy under the adjoint group $G_0$ of $\mathfrak {g}_0$ ; one therefore also speaks of the carrier algebra of e in $\mathfrak {g}$ . Moreover, two nonzero nilpotent elements of $\mathfrak {g}_1$ are $G_0$ -conjugate if and only if their carrier algebras are $G_0$ -conjugate, which makes carrier algebras a useful tool for classifying nilpotent orbits (see Vinberg [Reference Vinberg24, Section 4]). For details on the classification of nilpotent orbits in real semisimple Lie algebras using carrier algebras defined over the real field we refer to Dietrich et al. [Reference Dietrich, de Graaf, Marrani and Origlia12, Reference Dietrich, de Graaf, Ruggeri and Trigiante13].

Vinberg [Reference Vinberg24, Theorem 4] showed that every carrier algebra is semisimple $\mathbb {Z}$ -graded with $\mathfrak {c}(e)_k\leq \mathfrak {g}_k$ for each $k\in \mathbb {Z}$ , and that carrier algebras are characterised by the following three conditions:

1. (V1) $\dim \mathfrak {c}(e)_0=\dim \mathfrak {c}(e)_1$ ;

2. (V2) $\mathfrak {c}(e)$ is normalised by a maximal toral subalgebra of $\mathfrak {g}_0$ ;

3. (V3) $\mathfrak {c}(e)$ is not a proper subalgebra of a reductive $\mathbb{Z}$ -graded subalgebra of $\mathfrak {g}$ of the same rank.

Moreover, [Reference Vinberg24, Theorem 2] shows that e is in generic (or general) position in $\mathfrak {c}(e)_1$ , that is, $[\mathfrak {c}(e)_0,e]=\mathfrak {c}(e)_1$ , so (V1) states that the adjoint action of $\mathfrak {c}(e)_0$ on $\mathfrak {c}(e)_1$ yields an étale representation for $\mathfrak {c}(e)_0$ .

Only property (V1) is intrinsic to $\mathfrak {c}(e)$ , whereas (V2) and (V3) are determined by its embedding in the ambient Lie algebra $\mathfrak {g}$ . Thus, to describe the Lie algebras that can appear as carrier algebras for nilpotent elements in semisimple Lie algebras, one must merely classify $\mathbb{Z}$ -graded Lie algebras with (V1); we call such an algebra an abstract carrier algebra. Every abstract carrier algebra is a direct sum of simple abstract carrier algebras, so to describe the possible étale modules $(\mathfrak {c}(e)_0,\mathrm {ad},\mathfrak {c}(e)_1)$ coming from semisimple carrier algebras, it is sufficient to focus on simple abstract carrier algebras in Lie algebras. In the next section we follow Djokovič’s description [Reference Djokovič14] (based on work by Vinberg [Reference Vinberg24]) of the classification of all simple abstract carrier algebras. Using a different terminology, Bala and Carter [Reference Bala and Carter2] have also obtained a classification for the classical case. These classifications determine the following proposition.

From Burde et al. [Reference Burde, Globke and Minchenko10] we know that there exist étale representations for reductive algebraic groups with a simple factor of type ${\mathrm {C}}$ . This shows the following corollary.

2.2 Simple abstract carrier algebras Lie algebras

Recall that the grading of a semisimple $\mathbb {Z}$ -graded Lie algebra $\mathfrak {g}$ with defining element $h\in \mathfrak {g}$ is determined by $\mathfrak {g}_k=\{x\in \mathfrak {g} : [h,x]=kx\}$ for $k\in \mathbb {Z}$ . Two $\mathbb {Z}$ -graded Lie algebras $\mathfrak {g}$ and $\mathfrak {g}'$ with defining elements h and $h'$ are isomorphic if there is a Lie algebra isomorphism $\varphi \colon \mathfrak {g}\to \mathfrak {g}'$ with $\varphi (h)=h'$ . Djokovič [Reference Djokovič14] classified, up to isomorphism, semisimple $\mathbb {Z}$ -graded Lie algebras in terms of weighted Dynkin diagrams. Let $\mathfrak {h}\leq \mathfrak {g}$ be a maximal toral subalgebra containing h, with corresponding root system $\Phi $ . Let $\Pi $ be a basis of simple roots such that $\alpha (h)\geqslant 0$ for every $\alpha \in \Pi $ . Let $\Delta (\mathfrak {g})$ be the Dynkin diagram of $\mathfrak {g}$ with respect to $\mathfrak {h}$ , with vertices labelled by $\Pi $ , and to each vertex $\alpha \in \Pi $ attach the integer $\alpha (h)$ . The resulting weighted Dynkin diagram is denoted by $\Delta (\mathfrak {g},h)$ . Now [Reference Djokovič14, Theorem 1] shows that there is a bijection between (isomorphism classes of) $\mathbb {Z}$ -graded semisimple Lie algebras $(\mathfrak {g},h)$ and (isomorphism classes of) weighted Dynkin diagrams $\Delta (\mathfrak {g},h)$ .

In the following, let $(\mathfrak {g},h)$ be simple $\mathbb{Z}$ -graded and define $\deg \alpha \in \mathbb{Z}$ for $\alpha \in \Phi $ by $x_\alpha \in \mathfrak {g}_{\deg \alpha }$ , where $x_\alpha \in \mathfrak {g}$ is a root vector corresponding to $\alpha $ . If $\deg \alpha =k$ , then $\alpha (h)x_\alpha =[h,x_\alpha ]=kx_\alpha $ , hence $\alpha (h)=k$ ; this shows that $\deg \alpha =\alpha (h)$ . If $r_k$ is the number of roots with degree k, then $\mathfrak {g}$ is an abstract carrier algebra if and only if $\dim \mathfrak {h} + r_0= r_1$ . It is shown in [Reference Djokovič14, page 374] that if $\mathfrak {g}$ is an abstract carrier algebra, then $\deg \alpha \in \{0,1\}$ for every simple root $\alpha \in \Pi $ . So for the classification it remains to determine the weighted Dynkin diagrams with weights $\{0,1\}$ such that $\dim \mathfrak {h}_0+r_0=r_1$ . The reductive subalgebra $\mathfrak {g}_0$ is then given by the subdiagram consisting of the vertices with weight $0$ . To illustrate the method, we include the full proof for type A. To keep the exposition short, for the other types we only describe the results and refer to [Reference Djokovič14, Section 4], [Reference Bala and Carter2, Section 3] and [Reference Vinberg24, page 30] for more details.

If $\mathfrak {g}_0=\mathfrak {h}$ is a maximal toral subalgebra, then $r_0=0$ and all labels in the weighted diagram are $1$ ; one says that $\mathfrak {g}$ is principal. In this case the $0$ -component of the carrier algebra is abelian.

Type A. Let $\mathfrak {g}=\mathfrak {sl}(n+1,\mathbb {C})$ . The diagonal matrix $h={\mathrm {diag}}(\lambda _1,\ldots ,\lambda _{n+1})$ is the defining element with $\lambda _1\geqslant \cdots \geqslant \lambda _{n+1}$ . Consider the root system $\Phi =\{\pm (\varepsilon _i-\varepsilon _j) : 1\leq i<j<n\}$ and basis $\Pi =\{\alpha _1,\ldots ,\alpha _n\}$ where each $\varepsilon _i$ maps h to $\lambda _i$ and $\alpha _i=\varepsilon _i-\varepsilon _{i+1}$ . Let $k= \lambda _1-\lambda _{n+1}$ and, for $i=0,\ldots ,k$ , let $d_i$ be the number of $\lambda _r$ with $\lambda _r=\lambda _1-i$ . A root $\pm (\varepsilon _i-\varepsilon _j)$ has degree $0$ if and only if $\lambda _i=\lambda _j=\lambda _1-r$ for some r, and for each r there are $d_r(d_r-1)$ possibilities for $\varepsilon _i$ and $\varepsilon _j$ . This implies that $r_0=\sum _{j=0}^k d_j(d_j-1)$ . In a similar way $r_1=\sum _{j=0}^{k-1} d_jd_{j+1}$ , and now a direct calculation shows that $n+r_0=r_1$ if and only if

$$ \begin{align*}(d_0-d_1)^2+(d_1-d_2)^2+\cdots+(d_{k-1}-d_k)^2+(d_0^2-1)+(d_k^2-1)=0;\end{align*} $$

to see the latter, note that $d_0+\cdots +d_k=n+1$ . In conclusion, $\mathfrak {g}$ is an abstract carrier algebra if and only if $d_0=\cdots =d_k=1$ and $k=n$ , which is equivalent to $\mathfrak {g}$ being principal.

Types B and D. Let $\mathfrak {g}=\mathfrak {so}(m,\mathbb {C})$ be realised as $\mathfrak {g}=\{X\in \mathfrak {gl}(m,\mathbb {C}):X^\top J=-JX\}$ where J is the matrix with $1$ s on its anti-diagonal and $0$ s elsewhere, and either $m=2n+1$ (with $n\geqslant 2$ ) or $m=2n$ (with $n\geqslant 4$ ). Write the defining element as $h={\mathrm {diag}}(\lambda _1,\ldots ,\lambda _m)$ with $\lambda _1\geqslant \cdots \geqslant \lambda _m$ . Since $hJ=-Jh$ , each $-\lambda _i = \lambda _{m+1-i}$ . It has been shown that there are $s\geqslant 1$ and integers $k_1>\cdots >k_s\geqslant 0$ such that, as multisets,

(2.2) $$ \begin{align}\{\lambda_1,\ldots,\lambda_m\}=\{ k_i,k_i-1,\ldots,1-k_i,-k_i : 1\leq i\leq s\} \end{align} $$

and $m=(2k_1+1)+\cdots +(2k_s+1)$ ; note that $0$ occurs s times in $\{\lambda _1,\ldots ,\lambda _m\}$ and $1$ occurs at least $s-1$ times, and so on. Conversely, for any such integers $k_1>\cdots >k_s\geqslant 0$ with $m=(2k_1+1)+\cdots +(2k_s+1)$ there is a defining element h whose eigenvalues satisfy (2.2). To determine the labelled Dynkin diagrams, one chooses the diagonal matrices in $\mathfrak {g}$ as maximal toral subalgebra, and then the following statements hold.

If $m=2n+1$ , then s is odd and $\lambda _{n+1}=0$ . The corresponding simple abstract carrier algebra $B(k_1,\ldots ,k_s)$ of type ${\mathrm {B}}_n$ has a weighted Dynkin diagram with labels $\lambda _1-\lambda _2,\ldots , \lambda _{n-1}-\lambda _n, \lambda _n$ , where $\lambda _n$ is the label of the shorter root; see [Reference Djokovič14, Figure 5]. In that figure the last label is given as $2\lambda _n$ which is a typo (see [Reference Bala and Carter2, pages 410–412]). If $s=1$ , then $\{\lambda _1,\ldots ,\lambda _m\}=\{n,n-1,\ldots , 1-n,-n\}$ and $B(n)$ is principal. If $s=3$ , then $\lambda _{n+1},\lambda _n=0$ and $0<\lambda _{n-1}$ , implying that the semisimple part of $\mathfrak {g}_0$ is a direct sum of algebras of type A. If $s\geqslant 5$ , then $\lambda _{n+1},\lambda _n,\lambda _{n-1}=0$ and that semisimple part is a direct sum of algebras of type A and one algebra of type B.

If $m=2n$ , then s is even and $\lambda _n=0$ . The corresponding abstract carrier algebra $D(k_1,\ldots ,k_s)$ of type ${\mathrm {D}}_n$ has a weighted Dynkin diagram with labels $\lambda _1-\lambda _2,\ldots , \lambda _{n-2}-\lambda _{n-1}, \lambda _{n-1},\lambda _{n-1}$ , where $\lambda _{n-2}-\lambda _{n-1}$ is the label of the vertex of degree $3$ connected to the two vertices of degree 1 with label $\lambda _{n-1}$ (see [Reference Djokovič14, Figure 6]). If $s\geqslant 6$ , then $\lambda _n,\lambda _{n-1},\lambda _{n-2}=0$ and the semisimple part of $\mathfrak {g}_0$ is a direct sum of algebras of type A and one algebra of type D. If $s=2$ and $k_2>0$ , or $s=4$ , then that semisimple part is a direct sum of algebras of type A; if $s=2$ and $k_2=0$ , then $D(n-1,0)$ is principal.

Type C. Let $\mathfrak {g}=\mathfrak {sp}(2n,\mathbb {C})$ be realised as $\mathfrak {g}=\{X\in \mathfrak {gl}(2n,\mathbb {C}):X^\top S=-SX\}$ where S has the identity matrix $I_n$ and the negative $-I_n$ on its anti-diagonal. The simple abstract carrier algebras have the form $C(k_1,\dots ,k_s)$ and the construction is similar to those for type B and D. Here we can assume the defining element is $h={\mathrm {diag}}(\lambda _1,\ldots ,\lambda _n,-\lambda _n,\ldots ,-\lambda _1)$ with $\lambda _1\geqslant \cdots \geqslant \lambda _n>0$ and, as multisets, $\{\pm \lambda _1,\ldots ,\pm \lambda _n\}=\{k_i-\tfrac {1}{2},k_i-\tfrac {3}{2},\ldots ,\tfrac {3}{2}-k_i,\tfrac {1}{2}-k_i : 1\leq i\leq s\}$ for some $k_1>k_2>\cdots > k_s>0$ with $n=k_1+\cdots +k_n$ . If one chooses the diagonal matrices in $\mathfrak {g}$ as maximal toral subalgebra, then the Dynkin diagram of $C(k_1,\ldots ,k_s)$ has labels $\lambda _1-\lambda _2,\ldots ,\lambda _{n-1}-\lambda _n,2\lambda _n$ , where $2\lambda _n$ is attached to the longer root (see [Reference Djokovič14, Figure 7]). Since $\lambda _n\ne 0$ , we have $2\lambda _n=1$ , and so the semisimple part of $\mathfrak {g}_0$ is a direct sum of algebras of type A. If $s=1$ , then $C(n)$ is principal.

Exceptional types. A direct calculation yields the abstract carrier algebras $\mathfrak {g}$ of exceptional types ${\mathrm {G}}_2$ , ${\mathrm {F}}_4$ , ${\mathrm {E}}_6$ , ${\mathrm {E}}_7$ , ${\mathrm {E}}_8$ ; the semisimple part of $\mathfrak {g}_0$ is always a sum of Lie algebras of type A (see [Reference Vinberg24, Table 1]).

The centre of ${\mathfrak {g}_0}$ . Let $\mathfrak {g}_0$ be as before and write $\mathfrak {g}_0=\mathfrak {z}\oplus \mathfrak {s}$ where $\mathfrak {z}$ is the centre and $\mathfrak {s}$ is semisimple. It follows from [Reference Vinberg24, page 19] that $\dim \mathfrak {z}=\operatorname {{\mathrm {rk}}}\mathfrak {g}_0-\operatorname {{\mathrm {rk}}}\mathfrak {s}=\operatorname {{\mathrm {rk}}}\mathfrak {g}-\operatorname {{\mathrm {rk}}}\mathfrak {s}$ . Since $\operatorname {{\mathrm {rk}}} \mathfrak {s}$ equals the number of labels $0$ in the weighted Dynkin diagram of $\mathfrak {g}$ , the dimension of $\mathfrak {z}$ equals the number of labels $1$ . For example, if $\mathfrak {g}=B(5,2,1)$ with rank $9$ , then $\lambda _1,\ldots ,\lambda _9= 5,4,3,2,2,1,1,1,0$ , yielding labels $1,1,1,0,1,0,0,1,0$ ; thus, $\dim \mathfrak {z}=5$ . From the above classification, it follows that $\dim \mathfrak {z}=1$ if and only if $\mathfrak {g}$ has type ${\mathrm {A}}_1$ or if $\mathfrak {g}$ is the $\mathbb {Z}$ -graded algebra ${\mathrm {E}}_8^{(11)}$ , ${\mathrm {F}}_4^{(4)}$ or ${\mathrm {G}}_2^{(2)}$ as defined in [Reference Djokovič14, Table II].

3.1 Minimal Levi subalgebras

First, we recall a few definitions. Let $\mathfrak {g}=\mathfrak {z}\oplus \mathfrak {s}$ be a reductive Lie algebra with $\mathfrak {s}$ semisimple and $\mathfrak {z}=\mathfrak {z}(\mathfrak {g})$ the centre. A Borel subalgebra of $\mathfrak {g}$ is a maximal solvable subalgebra of $\mathfrak {g}$ , and a subalgebra of $\mathfrak {g}$ is a parabolic subalgebra if it contains a Borel subalgebra of $\mathfrak {g}$ . Every parabolic subalgebra $\mathfrak {p}$ of $\mathfrak {g}$ is a semidirect product $\mathfrak {p} = \mathfrak {m}\ltimes \mathfrak {n}$ of a nilpotent ideal $\mathfrak {n}$ of $\mathfrak {p}$ , all of whose elements are nilpotent, and a reductive subalgebra $\mathfrak {m}$ . A parabolic subalgebra is distinguished if $\dim \mathfrak {n}/[\mathfrak {n},\mathfrak {n}]=\dim \mathfrak {m}$ . Any reductive subalgebra $\mathfrak {m}$ of $\mathfrak {g}$ arising in this way for some parabolic subalgebra of $\mathfrak {g}$ is a Levi subalgebra in $\mathfrak {g}$ . Its commutator $\mathfrak {c}=[\mathfrak {m},\mathfrak {m}]$ is semisimple of parabolic type. Bala and Carter defined the terms above for semisimple $\mathfrak {g}$ , but they carry over without change to reductive $\mathfrak {g}$ .

For semisimple $\mathfrak {g}$ , it is shown in [Reference Bala and Carter3, Theorem 6.1] that the classification of nilpotent orbits is equivalent to the classification of conjugacy classes of pairs $(\mathfrak {c},\mathfrak {q}_{\mathfrak {c}})$ , where $\mathfrak {c}$ is semisimple subalgebra of parabolic type in $\mathfrak {g}$ and $\mathfrak {q}_{\mathfrak {c}}$ is a distinguished parabolic subalgebra of $\mathfrak {c}$ . For a nonzero nilpotent element $e\in \mathfrak {g}$ with $\mathfrak {sl}_2$ -triple $(h,e,f)$ , define $\mathfrak {g}_k=\{x\in \mathfrak {g} : [h,x]=kx\}$ for $k\in \mathbb {Z}$ ; this furnishes $\mathfrak {g}$ with a $\mathbb {Z}$ -grading. With this grading, $e\in \mathfrak {g}_2$ . The element e is distinguished in $\mathfrak {g}$ if $\mathrm {ad}(e)\colon \mathfrak {g}_0\to \mathfrak {g}_2$ is an isomorphism, that is, if e is in general position. If e is not distinguished in $\mathfrak {g}$ , then [Reference Bala and Carter3, Propositions 5.3 and 5.4] tell us how to construct a semisimple subalgebra $\mathfrak {c}$ of $\mathfrak {g}$ in which e is distinguished: if $\mathfrak {h}_0$ is a maximal toral subalgebra of the centraliser of $(h,e,f)$ in $\mathfrak {g}$ , then

(3.1) $$ \begin{align} \mathfrak{m} =\mathfrak{z}_{\mathfrak{g}}(\mathfrak{h}_0)\quad\text{and}\quad \mathfrak{c}=[\mathfrak{m},\mathfrak{m}] \end{align} $$

are a minimal Levi subalgebra of $\mathfrak {g}$ containing e and a semisimple subalgebra of parabolic type, respectively, such that e is distinguished in $\mathfrak {c}$ . The pair corresponding to e can be chosen to be $(\mathfrak {c},\mathfrak {q}_{\mathfrak {c}})$ , where $\mathfrak {q}_{\mathfrak {c}}$ is the Jacobson–Morozov parabolic (see [Reference Bala and Carter2, Proposition 4.3] and [Reference Bala and Carter3, Theorem 6.1]). If G is a semisimple algebraic group with Lie algebra $\mathfrak {g}$ , then $\mathfrak {c}$ is determined uniquely up to the action by $\mathrm {Z}_G(e)$ , the centraliser of e in $\mathrm {Ad}_{\mathfrak {g}}(G)$ . Since e is distinguished in $\mathfrak {c}$ , the $\mathbb {Z}$ -grading of its $\mathfrak {sl}_2$ -triple in $\mathfrak {c}$ yields an étale representation for the adjoint action of the reductive subalgebra $\mathfrak {c}_0$ on the subspace $\mathfrak {c}_2$ by evaluation at e. The adjoint action of $\mathfrak {g}$ integrates to that of G, and thus we obtain an étale representation of the reductive group with Lie algebra $\mathfrak {c}_0$ on the space $\mathfrak {c}_2$ .

The Borel and parabolic subalgebras of a reductive $\mathfrak {g}=\mathfrak {s}\oplus \mathfrak {z}$ as above are precisely $\mathfrak {z}\oplus \mathfrak {b}$ and $\mathfrak {z}\oplus \mathfrak {p}$ , respectively, with $\mathfrak {b}\leq \mathfrak {s}$ a Borel subalgebra and $\mathfrak {p}\leq \mathfrak {s}$ parabolic. It follows that the Levi subalgebras of $\mathfrak {g}$ are precisely $\mathfrak {z}\oplus \mathfrak {m}$ , where $\mathfrak {m}$ is a Levi subalgebra of $\mathfrak {s}$ ; moreover, $\mathfrak {m}$ is a minimal Levi subalgebra containing e in $\mathfrak {s}$ if and only if $\mathfrak {z}\oplus \mathfrak {m}$ is a minimal Levi subalgebra containing e in $\mathfrak {g}$ .

3.2 Relation to carrier algebras

We compare the Bala and Carter construction with Vinberg’s carrier algebras. Vinberg starts with a semisimple $\mathbb {Z}_n$ -graded Lie algebra $\mathfrak {g}=\bigoplus _{i\in \mathbb {Z}_n}\mathfrak {g}_i$ ; recall that we allow $\mathbb {Z}_\infty =\mathbb {Z}$ here. Let $e\in \mathfrak {g}_1$ be nonzero nilpotent with $\mathfrak {sl}_2$ -triple $(h,e,f)$ such that $h\in \mathfrak {g}_0$ and $f\in \mathfrak {g}_{-1}$ and define $\mathfrak {g}(\mathfrak {t},e)$ as in (2.1); as mentioned before, $\mathfrak {t}$ is a maximal toral subalgebra of the normaliser $\mathfrak {n}_{\mathfrak {g}_0}(e)$ and $\lambda \colon \mathfrak {t}\to \mathbb {C}$ is defined by $[t,e]=\lambda (t)e$ . Let $h_0=\tfrac 12h$ define the $\mathbb {Z}$ -graded algebra

$$ \begin{align*}\mathfrak{g}(h_0)=\bigoplus_{k\in\mathbb{Z}} \mathfrak{g}(h_0)_k\quad\text{with } \mathfrak{g}(h_0)_k=\{x\in \mathfrak{g}_k : [h_0,x]=kx\}. \end{align*} $$

Note that $\mathfrak {t}\leq \mathfrak {g}(h_0)_0$ . It follows from [Reference Vinberg24, Lemmas 1 and 2] that $\mathfrak {g}(h_0)$ and $\mathfrak {g}(\mathfrak {t},e)$ are both reductive. Recall that $\mathfrak {t}=\mathbb {C} h\oplus \mathfrak {t}_0$ , where $\mathfrak {t}_0$ is a maximal toral subalgebra of $\mathfrak {z}_{\mathfrak {g}_0}(h,e,f)$ . More precisely, we can state the following lemma.

The next proposition shows that Vinberg’s construction (2.1) of $\mathfrak {g}(\mathfrak {t},e)$ and its carrier algebra is the same as applying Bala and Carter’s approach (3.1) to the $\mathbb{Z}$ -graded Lie algebra $\mathfrak {g}(h_0)$ . Below, let G be the semisimple algebraic group with Lie algebra $\mathfrak {g}(h_0)$ . The conjugacy up to the centraliser $\mathrm {Z}_G(e)$ reflects the freedom in choosing an $\mathfrak {sl}_2$ -triple $(h,e,f)$ for a given nonzero nilpotent element e.

Proof. Note that h stabilises each $\mathfrak {g}_k$ and $\mathfrak {g}(h_0)_k$ is the intersection of $\mathfrak {g}_k$ with the $2k$ -eigenspace of h. Lemma 3.1 shows that $\mathfrak {g}(\mathfrak {t},e)\leq \mathfrak {g}(h_0)$ and the $\mathbb {Z}$ -gradings of both algebras are determined by the eigenvalues of $\mathrm {ad}(h_0)$ . The semisimple part $\mathfrak {s}$ of $\mathfrak {g}(h_0)$ is a semisimple ideal in $\mathfrak {g}(h_0)$ containing $(h,e,f)$ ; let $\mathfrak {a}$ be the subalgebra generated by $\{h,e,f\}$ . Note that for every subset $X\subseteq \mathfrak {g}(h_0)$ ,

(*) $$\begin{align} \mathfrak{z}_{\mathfrak{g}(h_0)}(X) = \mathfrak{z}(\mathfrak{g}(h_0))\oplus\mathfrak{z}_{\mathfrak{s}}(X).\end{align}$$

We claim that $\mathfrak {t}_0$ is a maximal toral subalgebra of $\mathfrak {z}_{\mathfrak {g}(h_0)}(\mathfrak {a})$ : recall that $\mathfrak {t}_0$ is defined as a maximal toral subalgebra of $\mathfrak {z}_{\mathfrak {g}_0}(\mathfrak {a})$ , which is reductive by [Reference Vinberg24, page 21]. Since $\mathfrak {t}_0\leq \mathfrak {g}(h_0)_0\leq \mathfrak {g}_0$ , we know that $\mathfrak {t}_0$ is also a maximal toral subalgebra in $\mathfrak {z}_{\mathfrak {g}(h_0)_0}(\mathfrak {a})$ . On the other hand, $\mathfrak {z}_{\mathfrak {g}(h_0)_0}(\mathfrak {a})=\mathfrak {z}_{\mathfrak {g}(h_0)}(\mathfrak {a})$ because elements of nonzero degree in $\mathfrak {g}(h_0)$ do not commute with the defining element $h_0\in \mathfrak {a}$ ; thus, $\mathfrak {t}_0\leq \mathfrak {z}_{\mathfrak {g}(h_0)}(\mathfrak {a})$ is a maximal toral subalgebra. We can write $\mathfrak {t}_0 = \mathfrak {z}(\mathfrak {g}(h_0)) \oplus \mathfrak {t}_0'$ , where $\mathfrak {t}_0'$ is a maximal toral subalgebra of $\mathfrak {z}_{\mathfrak {s}}(\mathfrak {a})$ , and so for every subset $X\subseteq \mathfrak {g}(h_0)$ ,

(**) $$\begin{align} \mathfrak{z}_{X}(\mathfrak{t}_0)=\mathfrak{z}_{X}(\mathfrak{t}_0'). \end{align}$$

The construction in (3.1) shows that $\mathfrak {m}'=\mathfrak {z}_{\mathfrak {s}}(\mathfrak {t}_0')$ is a minimal Levi subalgebra of $\mathfrak {s}$ containing e, so $\mathfrak {m}=\mathfrak {z}(\mathfrak {g}(h_0))\oplus \mathfrak {m}'$ is a minimal Levi subalgebra of $\mathfrak {g}(h_0)$ containing e. Now (*), (**) and Lemma 3.1 show

$$ \begin{align*} \mathfrak{m} = \mathfrak{z}(\mathfrak{g}(h_0))\oplus\mathfrak{z}_{\mathfrak{s}}(\mathfrak{t}_0') = \mathfrak{z}_{\mathfrak{g}(h_0)}(\mathfrak{t}_0') = \mathfrak{z}_{\mathfrak{g}(h_0)}(\mathfrak{t}_0) = \mathfrak{g}(\mathfrak{t},e), \end{align*} $$

so $\mathfrak {g}(\mathfrak {t},e)$ is a minimal Levi subalgebra in $\mathfrak {g}(h_0)$ containing e. The construction in (3.1) shows that e is distinguished in $[\mathfrak {m},\mathfrak {m}]$ and the latter is semisimple of parabolic type. Since $[\mathfrak {g}(\mathfrak {t},e),\mathfrak {g}(\mathfrak {t},e)]=[\mathfrak {m},\mathfrak {m}]$ is the carrier algebra, the claim follows; [Reference Bala and Carter3, Proposition 5.3] shows uniqueness up to $\mathrm {Z}_G(e)$ -conjugacy.

For a $\mathbb{Z}$ -graded semisimple Lie algebra $\mathfrak {g}$ , we have $\mathfrak {g}=\mathfrak {g}(h_0)$ where $h=2h_0$ is the defining element (see [Reference Dietrich, de Graaf, Ruggeri and Trigiante13, Remark 33]), so the two approaches by Vinberg and Bala and Carter coincide.

Even in the situation where $\mathfrak {g}$ is given without a grading and e is a nonzero nilpotent element in $\mathfrak {g}$ , a choice of $h_0$ induces a $\mathbb{Z}$ -grading on $\mathfrak {g}$ to which Vinberg’s approach can be applied; this is then equivalent to Bala and Carter’s approach. Note that Bala and Carter use the element h rather than $h_0=\tfrac 12h$ to define their grading, which leads to an additional factor of $2$ in the degrees.

4.1 Relation to carrier algebras

Gyoja’s construction was formulated for groups, but can just as well be formulated for the corresponding Lie algebras. For this let $\mathfrak {g}$ be a semisimple Lie algebra with nonzero nilpotent $e\in \mathfrak {g}$ , let $(h,e,f)$ be an $\mathfrak {sl}_2$ -triple in $\mathfrak {g}$ and furnish $\mathfrak {g}$ with the $\mathbb {Z}$ -grading induced by $\mathrm {ad}(h_0)$ , where $h_0=\tfrac {1}{2}h$ . Observe now that Gyoja’s method [Reference Gyoja15] replicates the aspect that is of interest to us in Vinberg’s and Bala and Carter’s theory: the focus is on the étale action of the reductive subalgebra of degree $0$ on the subspace of degree $1$ , ignoring the subspaces of higher degree.