\section{CDGA of Polynomials} \label{sec:cdga-of-polynomials} We will now give a cdga model for the $n$-simplex $\Delta^n$. This then allows for simplicial methods. In the following definition one should be reminded of the topological $n$-simplex defined as convex span. \Definition{apl}{ For all $n \in \N$ define the following cdga: $$ (\Apl)_n = \frac{\Lambda(x_0, \ldots, x_n, dx_0, \ldots, dx_n)}{(\sum_{i=0}^n x_i - 1, \sum_{i=0}^n dx_i)} $$ So it is the free cdga with $n+1$ generators and their differentials such that $\sum_{i=0}^n x_i = 1$ and in order to be well behaved $\sum_{i=0}^n dx_i = 0$. } Note that the inclusion $\Lambda(x_1, \ldots, x_n, dx_1, \ldots, dx_n) \to \Apl_n$ is an isomorphism of cdga's. So $\Apl_n$ is free and (algebra) maps from it are determined by their images on $x_i$ for $i = 1, \ldots, n$ (also note that this determines the images for $dx_i$). This fact will be used throughout. These cdga's will assemble into a simplicial cdga when we define the face and degeneracy maps as follows ($j = 1, \ldots, n$): $$ d_i(x_j) = \begin{cases} x_{j-1}, &\text{ if } i < j \\ 0, &\text{ if } i = j \\ x_j, &\text{ if } i > j \end{cases} \qquad d_i : \Apl_n \to \Apl_{n-1} $$ $$ s_i(x_j) = \begin{cases} x_{j+1}, &\text{ if } i < j \\ x_j + x_{j+1}, &\text{ if } i = j \\ x_j, &\text{ if } i > j \end{cases} \qquad s_i : \Apl_n \to \Apl_{n+1} $$ One can check that $\Apl \in \simplicial{\CDGA_\k}$. We will denote the subspace of homogeneous elements of degree $k$ as $\Apl^k \in \simplicial{\Mod{\k}}$, this is indeed a simplicial $\k$-module as the maps $d_i$ and $s_i$ are graded maps of degree $0$. \Lemma{apl-contractible}{ $\Apl^k$ is contractible. } \Proof{ We will prove this by defining an extra degeneracy $s: \Apl_n \to \Apl_{n+1}$. Define for $i = 1, \ldots, n$: \begin{align*} s(1) &= (1-x_0)^2 \\ s(x_i) &= (1-x_0) \cdot x_{i+1} \end{align*} Extend on the differentials and multiplicatively on $\Apl_n$. As $s(1) \neq 1$ this map is not an algebra map, however it well-defined as a map of cochain complexes. In particular when restricted to degree $k$ we get a linear map: $$ s: \Apl^k_n \to \Apl^k_{n+1}. $$ Proving the necessary properties of an extra degeneracy is fairly easy. For $n \geq 1$ we get (on generators): \begin{align*} d_0 s(1) &= d_0 (1 - x_0)^2 = (1 - 0) \cdot (1 - 0) = 1 \\ d_0 s(x_i) &= d_0((1-x_0)x_{i+1}) = d_0(1-x_0) \cdot x_i \\ &= (1-0) \cdot x_i = x_i \end{align*} So $d_0 s = \id$. \begin{align*} d_{i+1} s(1) &= d_{i+1} (1 - x_0)^2 = d_{i+1} (\sum_{j=1}^n x_j)^2 \\ &= (\sum_{j=1}^{n-1} x_j)^2 = (1-x_0)^2 = s d_i(1) \\ d_{i+1} s(x_j) &= d_{i+1}(1-x_0) d_{i+1}(x_j) = (1-x_0) d_i(x_{j+1}) = s d_i (x_j) \end{align*} So $d_{i+1} s = s d_i$. Similarly $s_{i+1} s = s s_i$. And finally for $n=0$ we have $d_1 s = 0$. So we have an extra degeneracy $s: \Apl^k \to \Apl^k$, and hence (see for example \cite{goerss}) we have that $\Apl^k$ is contractible. As a consequence $\Apl \to \ast$ is a weak equivalence. } \Lemma{apl-kan-complex}{ $\Apl_n^k$ is a Kan complex. } \Proof{ By the simple fact that $\Apl_n^k$ is a simplicial group, it is a Kan complex \cite{goerss}. } Combining these two lemmas gives us the following. \Corollary{apl-extendable}{ $\Apl^k \to \ast$ is a trivial fibration in the standard model structure on $\sSet$. } Besides the simplicial structure of $\Apl$, there is also the structure of a cochain complex. \Lemma{apl-acyclic}{ $\Apl_n$ is acyclic, i.e. $H(\Apl_n) = \k \cdot [1]$. } \Proof{ This is clear for $\Apl_0 = \k \cdot 1$. For $\Apl_1$ we see that $\Apl_1 = \Lambda(x_1, dx_1) \iso \Lambda D(0)$, which we proved to be acyclic in the previous section. For general $n$ we can identify $\Apl_n \iso \bigtensor_{i=1}^n \Lambda(x_i, dx_i)$, because $\Lambda$ is left adjoint and hence preserves coproducts. By the Künneth theorem \TheoremRef{kunneth} we conclude $H(\Apl_n) \iso \bigtensor_{i=1}^n H \Lambda(x_i, dx_i) \iso \bigtensor_{i=1}^n H \Lambda D(0) \iso \k \cdot [1]$. So indeed $\Apl_n$ is acyclic for all $n$. }