There is a variant of the Knudsen-Mumford moduli problem $\mathcal{M}_{g,n}$ of pointed curves, where one endows the $n$ marked points with non-zero tangent vectors. It shows up in the theory of vertex algebras as a home for central charge zero conformal blocks (and probably in other fields for reasons I don't know). Formally speaking, the objects in the category are diagrams $$S \rightrightarrows Frame(\Omega_{C/S}) \to C \to S,$$ where
- $C \to S$ is a smooth proper morphism with one dimensional connected genus $g$ geometric fibers,
- $Frame(\Omega_{C/S}) = \underline{Isom}(\Omega_{C/S}, \mathcal{O}_C) \to C$ is the canonical $\mathbb{G}_m$-torsor of nowhere vanishing relative tangents, and
- $S \rightrightarrows \underline{Isom}(\Omega_{C/S}, \mathcal{O}_C)$ are $n$ sections of the composite map to $S$, whose images in $C$ are pairwise disjoint.
It seems to be a folklore theorem that when $n(g+1) > 1$, this moduli problem is representable (in fact by a quasi-projective object), but I have been unable to locate a proof in the literature. For example, the book Lectures on tensor categories and modular functors by Bakalov and Kirillov only justifies it with the claim that these objects have trivial automorphism group.
It does not appear to be extremely difficult to prove - one may take a suitable principal torus bundle over Knudsen's scheme $H_{g,n}$ of tricanonically embedded pointed curves, and show that the corresponding action of $PGL(5g+3n-5)$ is free with suitably small orbits. The part about orbits seems like it might be a bit delicate, so I am curious:
Question: Is there a full proof of representability somewhere in the literature?
