Definition

A super $L_\infty$-algebra is an L-∞ algebra internal to the symmetric monoidal category of super vector spaces (i.e. in chain complexes of super vector spaces).

Definition

(super graded signature of a permutation)

Let $V$ be a $\mathbb{Z}$-graded super vector space, hence a $\mathbb{Z} \times (\mathbb{Z}/2)$-bigraded vector space.

For $n \in \mathbb{N}$ let

be an n-tuple of elements of $V$ of homogeneous degree $(n_i, s_i) \in \mathbb{Z} \times \mathbb{Z}/2$, i.e. such that $v_i \in V_{(n_i,s_i)}$.

For $\sigma$ a permutation of $n$ elements, write $(-1)^{\vert \sigma \vert}$ for the signature of the permutation, which is by definition equal to $(-1)^k$ if $\sigma$ is the composite of $k \in \mathbb{N}$ permutations that each exchange precisely one pair of neighboring elements.

We say that the super $\mathbf{v}$-graded signature of $\sigma$

is the product of the signature of the permutation $(-1)^{\vert \sigma \vert}$ with a factor of

for each interchange of neighbours $(\cdots v_i,v_j, \cdots )$ to $(\cdots v_j,v_i, \cdots )$ involved in the decomposition of the permuation as a sequence of swapping neighbour pairs (see at signs in supergeometry for discussion of this combination of super-grading and homological grading).

Definition

An super $L_\infty$-algebra is

1. a $\mathbb{Z} \times (\mathbb{Z}/2)$-graded vector space $\mathfrak{g}$;

2. for each $n \in \mathbb{N}$ a multilinear map, called the $n$-ary bracket, of the form

   $$l_n(\cdots) \;\coloneqq\; [-,-, \cdots, -]_n \;\colon\; \underset{n \; \text{copies}}{\underbrace{\mathfrak{g} \otimes \cdots \otimes \mathfrak{g}}} \longrightarrow \mathfrak{g}$$

   and of degree $n-2$

such that the following conditions hold:

1. (super graded skew symmetry) each $l_n$ is graded antisymmetric, in that for every permutation $\sigma$ of $n$ elements and for every n-tuple $(v_1, \cdots, v_n)$ of homogeneously graded elements $v_i \in \mathfrak{g}_{\vert v_i \vert}$ then

   $$l_n(v_{\sigma(1)}, v_{\sigma(2)},\cdots ,v_{\sigma(n)}) = \chi(\sigma,v_1,\cdots, v_n) \cdot l_n(v_1, v_2, \cdots v_n)$$

   where $\chi(\sigma,v_1,\cdots, v_n)$ is the super $(v_1,\cdots,v_n)$-graded signature of the permuation $\sigma$, according to def. ;

2. (strong homotopy Jacobi identity) for all $n \in \mathbb{N}$, and for all (n+1)-tuples $(v_1, \cdots, v_{n+1})$ of homogeneously graded elements $v_i \in \mathfrak{g}_{\vert v_i \vert}$ the followig equation holds

   (1)$$\sum_{{i,j \in \mathbb{N}} \atop {i+j = n+1}} \sum_{\sigma \in UnShuff(i,j)} \chi(\sigma,v_1, \cdots, v_{n}) (-1)^{i(j-1)} l_{j} \left( l_i \left( v_{\sigma(1)}, \cdots, v_{\sigma(i)} \right), v_{\sigma(i+1)} , \cdots , v_{\sigma(n)} \right) = 0 \,,$$

   where the inner sum runs over all $(i,j)$-unshuffles $\sigma$ and where $\chi$ is the super graded signature sign from def. .

A strict homomorphism of super $L_\infty$-algebras

is a linear map that preserves the bidegree and all the brackets, in an evident sens.

A strong homotopy homomorphism (“sh map”) of super $L_\infty$-algebras is something weaker than that, best defined in formal duals, below in def. .

Definition

A super $L_\infty$ algebra $\mathfrak{g}$ is of finite type if the underlying $\mathbb{Z} \times (\mathbb{Z}/2)$-graded vector space is degreewise of finite dimension.

If $\mathfrak{g}$ is of finite type, then its Chevalley-Eilenberg algebra $CE(\mathfrak{g})$ is the differential graded-commutative superalgebra whose underlying graded algebra is the super-Grassmann algebra

of the graded degreewise dual vector space $\mathfrak{g}^\ast$, equipped with the differential which on generators is the sum of the dual linear maps of the $n$-ary brackets:

and extended to all of $\wedge^\bullet \mathfrak{g}^\ast$ as a super-graded derivation of degree $(1,even)$.

Notice that here the signs in supergeometry are such that for $\alpha_i \in \mathfrak{g}^\ast_{(n_i,s_i)}$ elements of homogenous bidegree, then

and

(see at signs in supergeometry for more on this).

A strong homotopy homomorphism (“sh-map”) between super $L_\infty$-algbras of finite type

is defined to be a homomorphism of dg-algebras between their Chevalley-Eilenberg algebras going the other way:

(here $f^\ast$ is the primitive concept, and $f$ is defined as the formal dual of $f$). Hence the category of super $L_\infty$-algebras of finite type is the full subcategory

of the opposite category of differential graded-commutative superalgebras on those that are CE-algebras as above.

Finally, the cochain cohomology of the Chevalley-Eilenberg algebra $CE(\mathfrak{g})$ of a super $L_\infty$ algebra of finite type is its L-∞ algebra cohomology with coefficients in $\mathbb{R}$: