Proof

This follows from the long exact sequence of homotopy groups associated to the defining (∞,1)-pullback, using that

• $\mathbf{H}_{diff}(X, \mathbf{B}^3 U(1))$ is a 3-groupoid;

• $\mathbf{H}(X, \mathbf{B}Spin)$ is a 1-groupoid;

• $H^4_{diff}(X)$ is a 0-groupoid.

Proof

Elements in the defining homotopy pullback from def. over a given connection $\nabla \in \mathbf{H}(X,\mathbf{B} Spin)_{conn}$ are chracterized by an element $[\alpha] \in H^4_{diff}(X)$ and an equivalence

between the corresponding Chern-Simons circle 3-bundle and the given circle 3-bundle $\alpha$. In the case at hand, both have underlying trivial class $c(CS(\nabla)) = c(\alpha) = 0$.

By the characteristic class exact sequence

any two classes in $\pi_0 \mathbf{H}_{diff}(X, \mathbf{B}^3 U(1)) \simeq H^4_{diff}(X)$ that have trivial underlying class in $\pi_0 \mathbf{H}(X, \mathbf{B}^3 U(1)) \simeq H^4(X, \mathbb{Z})$ differ by a 3-form modulo a closed 3-form with integral periods.

Therefore both $[\alpha]$ as well as $[CS(\nabla)] \in H^4_{diff}(X)$ are given by a globally defined 3-form modulo an integral form: the global connection 3-form on these trivial circle 3-bundles with connection.

Proof

To see that the left morphism is objectwise a weak homotopy equivalence, notice that a $[k]$-cell of $\exp(b \mathbb{R} \to \mathfrak{g}_\mu)$ consists of a triple $(A,B,C)$, where $A$ is a vertical flat $\mathfrak{g}$-valued 1-form on $U\times\Delta^k$, $B$ is a vertical 2-form and $C$ a 3-form on $U\times\Delta^k$, such that $d B=C-\mu(A,A,A)$ and $d C=0$, since $A$ is flat. Therefore $C$ is uniquely determined by $A$ and $B$, and there are no conditions on $B$. This means that a $[k]$-cell of $\exp(b \mathbb{R} \to \mathfrak{g}_\mu)$ is identified with a pair consisting of a based smooth function $f : \Delta^k \to Spin$ and a vertical 2-form $B \in \Omega^2_{si,vert}(U \times \Delta^k)$, (both suitably with sitting instants perpendicular to the boundary of the simplex). Since there is no further condition on the 2-form, it can always be extended from the boundary of the $k$-simplex to the interior (for instance simply by radially rescaling it smoothly to 0). Accordingly the simplicial homotopy groups of $\exp(b \mathbb{R} \to \mathfrak{g}_\mu)(U)$ are the same as those of $\exp(\mathfrak{g})(U)$. The morphism between them is the identity in $f$ and picks $B = 0$ and is hence clearly an isomorphism on homotopy groups.

We turn now to discussing that the second morphism is a fibration. The nontrivial degrees of the lifting problem

are $k = 3$ and $k = 4$.

Notice that a $3$-cell of $\mathbf{B}^3 \mathbb{R}/ \mathbb{Z}_c(U)$ is a smooth function $U \to \mathbb{R}/\mathbb{Z}$ and that the morphism $\exp(b\mathbb{R} \to \mathfrak{g}_\mu) \to \mathbf{B}^3 \mathbb{R}/\mathbb{Z}_c$ sends the pair $(f,B)$ to the fiber integration $\int_{\Delta^3}(f^* \langle \theta \wedge [\theta \wedge \theta]\rangle + d B) mod \mathbb{Z}$.

Our lifting problem in degree 3, has given a function $c : U \times \Delta^3 \to \mathbb{R}/\mathbb{Z}$ and a smooth function (with sitting instants at the subfaces) $f : U \times \Lambda^3_i \to Spin$ together with a 2-form $B$ on the horn $U \times \Lambda^3_i$.

By pullback along the standard continuous retract $\Delta^3 \to \Lambda^3_i$ which is non-smooth only where $f$ has sitting instants, we can always extend $f$ to a smooth function $f' : U \times \Delta^3 \to Spin$ with the property that $\int_{\Delta^3} (f')^* \langle \theta \wedge [\theta \wedge \theta]\rangle = 0$. (Following the general discussion at Lie integration.)

In order to find a horn filler for the 2-form component, consider any smooth 2-form with sitting instants and non-vanishing integeral on $\Delta^2$, regarded as the missing face of the horn. By multiplying it with a suitable smooth function on $U$ we can obtain an extension $\tilde B \in \Omega^3_{si,vert}(U \times \partial \Delta^3)$ of $B$ to all of $U \times \partial \Delta^3$ with the property that its integral over $\partial \Delta^3$ is the given $c$. By the Stokes theorem it remains to extend $\tilde B$ to the interior of $\Delta^3$ in any way, as long as it is smooth and has sitting instants.

To that end, we can find in a similar fashion a smooth $U$-parameterized family of closed 3-forms $H$ with sitting instants on $\Delta^3$, whose integral over $\Delta^3$ equals $c$. Since by sitting instants this 3-form vanishes in a neighbourhood of the boundary, the standard formula for the Poincare lemma applied to it produces a 2-form $B' \in \Omega^2_{si, vert}(U \times \Delta^3)$ with $d B' = C$ that itself is radially constant at the boundary. By construction the difference $\tilde B - B'|_{\partial \Delta^3}$ has vanishing surface integral. By the discussion at Lie integration it follows that the difference extends smoothly and with sitting instants to a closed 2-form $\hat B \in \Omega^2_{si,vert}(U \times \Delta^3)$. Therefore the sum

equals $B$ when restricted to $\Lambda^k_i$ and has the property that its integral over $\Delta^3$ equals $c$. Together with our extension $f'$, this constitutes a pair that solves the lifting problem.

The extension problem in degree 4 amounts to a similar construction: by coskeletalness the condition is that for a given $c : U \to \mathbb{R}/\mathbb{Z}$ and a given vertical 2-form on $U \times \partial \Delta^3$ such that its integral equals $c$, as well as a function $f : U \times \partial \Delta^3 \to Spin$, we can extend the 2-form and the function along $U \times \partial \Delta^3 \to U \times \Delta^3$. The latter follows from the fact that $\pi_2 Spin = 0$ which guarantees a continuous filler (with sitting instants), and using the Steenrod-Wockel approximation theorem to make this smooth. We are left with the problem of extending the 2-form, which is the same problem we discussed above after the choice of $\tilde B$.

Proof

The following proof makes use of details discussed at differential string structure – proofs .

We discuss that the first morphism is an equivalence. Clearly it is injective on homotopy groups: if a sphere of $A$-data cannot be filled, then also adding the $(B,C)$-data does not yield a filler. So we need to check that it is also surjective on homotopy groups: if the $A$-data can be filled, then also the corresponding $(B,C)$-data has a filler. Since the curvature $H$ is horizontal it is already extended. We may extend $B$ in any smooth way to $U \times \Delta^k$ (for instance by rescaling it smoothly to zero at the center of the $k$-simplex) and then take the equation $d B = - CS(A) + C + H$ to define the extension of $C$.

We now check that the second morphism is a fibration. It is itself the composite

Here the second morphism is a degreewise surjection of simplicial abelian groups, hence a degreewise surjection under the normalized chain complex functor, hence is itself already a projective fibration. Therefore it is sufficient to show that the first morphism here is a fibration.

In degree $k = 0$ to $k = 3$ the lifting problems

may all be equivalently reformulated as lifting against a cylinder $D^k \hookrightarrow D^k \times [0,1]$ by using the sitting instants of all forms.

We have then a 3-form $C \in \Omega^3_{si}(U \times D^{k-1}\times [0,1])$ with horizontal curvature $\mathcal{G} \in \Omega^4(U)$ and differential form data $(A,B)$ on $U \times D^{k-1}$ given. We may always extend $A$ along the cylinder direction $[0,1]$ (its vertical part is equivalently a based smooth function to $Spin$ which we may extend constantly). $H$ has to be horizontal so it is to be constantly extended along the cylinder.

We can then use the kind of formula that proves the Poincare lemma to extend $B$. Let $\Psi : (D^k \times [0,1]) \times [0,1] \to (D^k \times [0,1])$ be a smooth contraction. Then while $d(H - CS(A) + C)$ may be non-vanishing, by horizonatlity of their curvature characteristic forms we still have that $\iota_{\partial_t} \Psi_t^* d(H - CS(A) + C)$ vanishes (since the contraction vanishes).

Therefore the 2-form

satisfies $d \tilde B = (H - CS(A) + C)$. It may however not coincide with our given $B$ at $t = 0$. But the difference $B - \tilde B|_{t = 0}$ is a closed form on the left boundary of the cylinder. We may find some closed 2-form on the other boundary such that the integral around the boundary vanishes. Then the argument from the proof of the Lie integration of the line Lie n-algebra applies and we find an extension $\lambda$ to a closed 2-form on the interior. The sum

then still satisfies $d \hat B = H - CS(A) - C$ and it coincides with $B$ on the left boundary.

Notice that here $\tilde B$ indeed has sitting instants: since $H$, $CS(A)$ and $C$ have sitting instants they are constant on their value at the boundary in a neighbourhood perpendicular to the boundary, which means for these 3-forms in the degrees $\leq 3$ that they vanish in a neighbourhood of the boundary, hence that the above integral is towards the boundary over a vanishing integrand.

In degree 4 the nature of the lifting problem

starts out differently, due to the presence of $\mathbf{cosk}_3$, but it then ends up amounting to the same kind of argument:

We have four functions $U \to \mathbb{R}/\mathbb{Z}$ which we may realize as the fiber integration of a 3-form $C$ on $U \times (\partial \Delta[4] \setminus \delta_i \Delta[3])$, and we have a lift to $(A,B,C, H)$-data on $U \times (\partial \Delta[4]\setminus \delta_i(\Delta[3]))$ (the boundary of the 4-simplex minus one of its 3-simplex faces).

We observe that we can

• always extend $C$ smoothly to the remaining 3-face such that its fiber integration there reproduces the signed difference of the four given functions corresponding to the other faces (choose any smooth 3-form with sitting instants and with non-vanishing integral and rescale smoothly);

• fill the $A$-data horizonatlly due to the fact that $\pi_2 (Spin) = 0$.

• the $H$-form is already horizontal, hence already filled.

Moreover, by the fact that the 2-form $B$ already is defined on all of $\partial \Delta[4] \setminus \delta_i(\Delta[3])$ its fiber integral over the boundary $\partial \Delta[3]$ coincides with the fiber integral of $H - CS(A) + C$ over $\partial \Delta[4] \setminus \delta_i (\Delta[3])$). But by the fact that we have lifted $C$ and the fact that $\mu(A_{vert}) = CS(A)|_{\Delta^3}$ is an integral cocycle, it follows that this equals the fiber integral of $C - CS(A)$ over the remaining face.

Use then as above the vertical Poincare lemma-formula to find $\tilde B$ on $U \times \Delta^3$ with sitting instants that satisfies the equation $d B = H - CS(A) + C$ there. Then extend the closed difference $B - \tilde B|_{0}$ to a closed smooth 2-form on $\Delta^3$. As before, the difference

is an extension of $B$ that constitutes a lift.

Proof

Since $[CartSp_{smooth}^{op}, sSet]_{proj}$ is a simplicial model category the morphism $[CartSp^{op}, sSet](\hat X,\exp(\mu,cs))$ is a fibration because $\exp(\mu,cs)$ is and $\hat X$ is cofibrant.

It follows from the discussion at homotopy pullback that the ordinary pullback of simplicial presheaves

is a presentation for the defining (∞,1)-pullback for $String_{diff,tw}(X)$, as defined above.

Proof

By the above discussion of Cech cocycles we compute $String_{diff, tw = 0}(X)$ as the ordinary fiber of the morphism of simplicial presheaves

over the identically vanishing cocycle.

In terms of the component formulas spelled out in the above discussion of the GS-mechanism, this amounts to restricting to those cocycles for which in each degree the equations

holds.

Comparing this to the explicit formulas for $\exp(b \mathbb{R} \to \mathfrak{g}_\mu)$ and $\exp(b \mathbb{R} \to \mathfrak{g}_\mu)_{conn}$ in the above we see that these cocycles are exactly those that factor through the canonical inclusion

from observation of the string Lie 2-algebra into the mapping cone Lie 3-algebra of the extension $b \mathbb{R} \to \mathfrak{g}_\mu \to \mathfrak{g}$ that defines it.