A Poisson manifold is a pair $(M, \{\cdot, \cdot\}_M)$ where $M$ is a manifold and $$\{\cdot, \cdot\}: C^\infty(M)\times C^\infty(M)\longrightarrow C^\infty(M)$$ is a Lie bracket such that $$\{f, gh\}=g\{f, h\}+\{f, g\} h.$$ I read $\{\cdot, \cdot\}$ induces a Poisson bivector $\Pi$, that is, a section of the second exterior power of $TM$, that is, $\Pi\in \Gamma(\Lambda^2 TM)$, by: $$\Pi(df, dg):=\{f, g\}.$$ I know that $$\Gamma(\Lambda^2 TM)\simeq \textrm{Alt}^2_{C^\infty(M)}(\Omega^1(M), C^\infty(M)),$$ where $\Omega^1(M)$ is the space of $1$-forms on $M$ and $\textrm{Alt}^2_{C^\infty}$ is the space of alternating $C^\infty(M)$-bilinear maps.
Can anyone explain me the definition of $\Pi$. Why is $\Pi$ evaluated on $df$ and $dg$?
Thanks