\subsection{The free cdga} \label{sec:free-cdga} Just as in ordinary linear algebra we can form an algebra from any graded module. Furthermore we will see that a differential induces a derivation. \begin{definition} The \emph{tensor algebra} of a graded module $M$ is defined as $$ T(M) = \bigoplus_{n\in\N} M^{\tensor n}, $$ where $M^{\tensor 0} = \k$. An element $m = m_1 \tensor \ldots \tensor m_n$ has a \emph{word length} of $n$ and its degree is $\deg{m} = \sum_{i=i}^n \deg{m_i}$. The multiplication is given by the tensor product (note that the bilinearity follows immediately). \end{definition} Note that this construction is functorial and it is free in the following sense. \begin{lemma} Let $M$ be a graded module and $A$ a graded algebra. \begin{itemize} \item A graded map $f: M \to A$ of degree $0$ extends uniquely to an algebra map $\overline{f} : TM \to A$. \item A differential $d: M \to M$ extends uniquely to a derivation $d: TM \to TM$. \end{itemize} \end{lemma} \begin{corollary} Let $U$ be the forgetful functor from graded algebras to graded modules, then $T$ and $U$ form an adjoint pair: $$ T: \grMod{\k} \leftadj \grAlg{\k} :U $$ Moreover it extends and restricts to $$ T: \dgMod{\k} \leftadj \dgAlg{\k} :U $$ $$ T: \CoCh{\k} \leftadj \DGA{\k} :U $$ \end{corollary} As with the symmetric algebra and exterior algebra of a vector space, we can turn this graded tensor algebra in a commutative graded algebra. \begin{definition} Let $A$ be a graded algebra and define $$ I = < ab - (-1)^{\deg{a}\deg{b}}ba \I a,b \in A >. $$ Then $A / I$ is a commutative graded algebra. For a graded module $M$ we define the \emph{free commutative graded algebra} as $$ \Lambda(M) = TM / I $$ \end{definition} Again this extends to differential graded modules (i.e. the ideal is preserved by the derivative) and restricts to cochain complexes. \begin{lemma} We have the following adjunctions: $$ \Lambda: \grMod{\k} \leftadj \grAlg{\k}^{comm} :U $$ $$ \Lambda: \dgMod{\k} \leftadj \dgAlg{\k}^{comm} :U $$ $$ \Lambda: \CoCh{\k} \leftadj \CDGA_\k :U $$ \end{lemma} We can now easily construct cdga's by specifying generators and their differentials.