Construction and Proof

We describe first the addition of tangent vectors, then the $R$-action on them and then prove that this is a module-structure.

• Addition With $D = \{\epsilon \in R| \epsilon^2 = 0 \}$ the infinitesimal interval and $D(2) = \{(\epsilon_1, \epsilon_2) \in R \times R | \epsilon_i^2 = 0\}$ we have a cocone

  $$\array{ D(2) &\leftarrow& D \\ \uparrow && \uparrow \\ D &\leftarrow& {*} }$$

  such that

  $$\array{ R^{D(2)} &\to & R^D \\ \downarrow && \downarrow \\ R^D &\to& R }$$

  is a limit cone, by the Kock-Lawvere axiom satisfied in the smooth topos $\mathcal{T}$. Since $X$ is microlinear, also the canonical map

  $$r \colon X^{D(2)} \to X^D \times_X X^D$$

  is an isomorphism. With $\Id \times Id : D \to D(2)$ the diagonal map, we then define the fiberwise addition $X^D \times_X X^D \to X^D$ in the tangent bundle $X^D$ to be given by the map

  $$+ : X^D \times_X X^D \stackrel{r^{-1}}{\to} X^{D(2)} \stackrel{X^{Id \times Id}}{\to} X^D \,.$$

  On elements, this sends two elements $v_1, v_2 \in X^D$ in the same fiber to the element $v_1 + v_2$ of $X^D$ given by the map $(v_1 + v_2) : d \mapsto r^{-1}(v_1,v_2)(d,d)$.

• Multiplication $\cdot : R \times X^D \to X^D$ is defined componentwise by

  $(\alpha \cdot v) : d \mapsto v (\alpha \cdot d)$.

One checks that this is indeed unital, associative and distributive. …

Proof

This is obvious from the standard properties of limits and the fact that the internal hom-functor $(-)^Y : \mathcal{T} \to \mathcal{T}$ preserves limits. (See limits and colimits by example if you don’t find it obvious.)

1. by definition

2. Let $\Delta$ be the tip of a cocone $\Delta_j$ of infinitesimal spaces such that $\lim_j R^{\Delta_j} = R^\Delta$. Then

   $$\begin{aligned} X^{\Delta} &= (\lim_i X_i)^\Delta \\ &\simeq \lim_i X_i^{\Delta} \\ & \simeq \lim_i \lim_j X_i^{\Delta_j} \\ & \simeq \lim_j \lim_i X_i^{\Delta_j} \\ & \simeq \lim_j X^{\Delta_j} \end{aligned}$$

3. with $\Delta$ as above we have (writing $[A,B]$ for the internal hom otherwise equivalently denoted $B^A$)

   $$\begin{aligned} [\Delta, [\Sigma, X]] & \simeq [\Delta \times \Sigma, X] \\ & \simeq [\Sigma, [\Delta, X]] \\ & \simeq [\Sigma, \lim_j [\Delta_j, X]] \\ & \simeq \lim_j [\Sigma, [\Delta_j, X]] \\ & \simeq \lim_j [\Delta_j, [\Sigma, X]] \end{aligned}$$

Proof

For $\mathcal{F}$ and $\mathcal{G}$ this is the statement of MSIA, chapter V, section 7.1.

For $\mathcal{Z}$ and $\mathcal{B}$ the argument is similarly easy:

These are categories of sheaves on the full category $\mathbb{L} = (C^\infty Ring^{fin})^{op}$. The line object $R$ is representable in each case, $R = \ell C^\infty(\mathbb{R})$. Every object in $\mathbb{L}$ is a limit (not necessarily finite) over copies of $R$ in $\mathbb{L}$. Accordingly, every object $\ell A$ of $\mathbb{L}$ satisfies the microlinearity axioms in $\mathbb{L}$ in that for each cocone $\Delta \to \Delta_c : J \to \mathbb{L}$ of infinitesimal objects such that $R^{\Delta_c} \simeq \lim_{j \in J} R^{\Delta_j}$ we also have $(\ell A)^{\Delta_c} \simeq \lim_{j \in J} (\ell A)^{\Delta_j}$. Now, the Yoneda embedding $Y : \mathbb{L} \to PSh(C)$ preserves limits and exponentials. Since the Grothendieck topology in question is subcanonical, $Y((\ell A)^{\Delta_j})$ is in $Sh(C)$ and hence is the exponential object $Y(\ell A)^{Y \Delta_j}$ there. Finally, the finite limit over $J$ is preserved by the reflection $PSh(C) \to Sh(C)$ (sheafification, which acts trivially on our representables), so $Y(\ell A)^{\Delta_c} \simeq \lim_{j \in J} Y(\ell A)^{Y(\Delta_j)}$ and hence all $Y(\ell A)$ are microlinear in $\mathcal{Z}$ and $\mathcal{B}$.