The Algebraic Hartogs Lemma states that in a Noetherian normal scheme, a rational function that is regular outside a closed subset of codimension at least two, is in fact regular everywhere.

In a research problem I was working on recently, I was (following suggestions by my advisor) using this to prove that a particular section of a line bundle existed on a space $\mathbb{A}^n_H$. The argument worked well when $H$ was a point. For more general $H$, I could show that the section was defined except on a codimension-two subset of every fiber; but it was not immediately obvious to me how to go from there, to showing that the section was defined "on all fibers simultaneously," i.e., over $\mathbb{A}^n_H$. This was especially problematic in that the base scheme $H$ in question was a component of a Hilbert scheme, and thus (as shown by Ravi Vakil) capable of exhibiting arbitrarily bad behavior. In particular, the fact that a composition of normal morphisms is normal (see EGA IV.2, section 6.8) would not come close to covering my situation.

In order to deal with this, I have obtained what seems to be a proof of the following statement:

Lemma (Relative Algebraic Hartogs' Lemma) Let $X \to S$ be a flat, finite-type morphism of Noetherian schemes such that every associated fiber is normal. Let $\mathscr{L}$ be a line bundle on $X$. Suppose that $U \subset X$ is an open subscheme such that
(i) $U$ contains all the associated points of $X$,
(ii) for every $s \in S$, $U \cap X_s$ contains all the associated points of $X_s$, and
(iii) for every associated point $\eta$ of $S$, $U$ contains all but a codimension-two closed subset of $X_{\eta}$.
Then the restriction map $$\Gamma(X,\mathscr{L}) \to \Gamma(U,\mathscr{L})$$ is an isomorphism.

(I'm using "associated fiber" to mean "fiber over an associated point," by analogy with the standard term "generic fiber.")

I should note that suggestions of Will Sawin in this answer were invaluable in coming up with the proof.

This lemma is surprisingly strong, in that two key hypotheses--normality, and codimension-two-ness--only need to hold "generically" (i.e., in the fibers over the associated points). Another interesting feature is that, if you look at the proof, the fibers do not actually have to be normal, as long as they "satisfy the Hartogs property"--which I understand is equivalent to satisfying the S2 condition. I'm also not convinced that the finite-type hypothesis is necessary, but I have not yet verified the argument that I suspect would remove it.

The proof is not incredibly long (4 pages from me; probably less from a more experienced mathematician who knows what details to leave out), uses only techniques that are extremely well known, and so far as I can tell, does not use them in an especially clever way. Thus, it seems likely that someone, at some point, has already written up a similar result. However, neither I, nor my advisor, nor anyone else I have spoken to was familiar with it (which suggests to me that, if nothing else, the result is less well-known than it should be). Hence, my question:

Question: Does anyone know of a similar statement in the literature? (To be safe, I'll also ask if anyone knows of any counterexamples, although I think the proof is solid.)

One final note: From what I understand, the popularity of the name "algebraic hartogs lemma" is quite recent, possibly a result of its use in Ravi Vakil's notes, so a similar result in the older literature would probably not be called by the word "Hartogs."

Update: I have posted a proof of the Lemma above.

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    The name "algebraic Hartogs lemma", in my opinion, is an inaccurate choice, since it is not the algebro geometric equivalent of Hartogs Lemma in complex analysis (which involves extension of holomorphic functions through compact holes in a domain), but it is exactly the algebro geometric analog of the so called "second Riemann extension theorem" in analytic geometry (involving extension of holomorpic functions through analytic subsets of codimension at least 2). [...] – Qfwfq Feb 2 '12 at 21:50
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    [...][BTW, There is also a "first Riemann extension theorem" (wich is about extending bounded holomorphic functions through analytic subsets of any codimention)]. For a reference see e.g. Fritzsche, Grauert, "From holomorphic functions to complex manifolds". – Qfwfq Feb 2 '12 at 21:50
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    Martin: The commutative algebra tag is there because my proof consists almost entirely of commutative algebra, followed by a brief bit afterwards explaining why the algebraic statement implies the "geometric" language. (From what I can tell, Sándor Kovács's version has a very different flavor, relying instead on local cohomology / cohomology with supports.) Although I did not think through my tag choice as carefully as the rest of the question, it stands to reason that there might be another "similar statement" in the literature that is phrased algebraically, so it makes sense to (cont.) – Charles Staats Feb 2 '12 at 22:32
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    Perhaps one can quibble about the accuracy of "Hartogs" but I like it, and vote to keep it. – Donu Arapura Feb 3 '12 at 13:20
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    At some point I called the result we are discussing (not Charles' very nice relative version) algebraic Hartogs', and said that it might be nonstandard. A colleague (who I will not name, as I don't want to misquote him --- but it will be obvious who I mean) said "who doesn't call it that?. As I take him as one of the arbiters of (my opinion of) mathematical good taste, I've stuck with it. A distinctive and memorable name helps people remember the result. So despite Qfwfq's excellent point, I intend to keep calling it that, and argue in favor of it. But I intend to also mention ... – Ravi Vakil Feb 6 '12 at 1:09
up vote 12 down vote accepted

Actually, a very similar statement can be found in the paper Reflexive pull-backs and base extension by Brendan Hassett and myself. See Proposition 3.5. Indeed you do not need normality, only that the fibers are $S_2$ and the sheaf does not need to be a line bundle only coherent and flat over the base. We develop a little bit of a relative theory in section 3, so you might find the rest useful as well, especially the statement regarding a characterization via local cohomology. We did assume the codimension two condition for every fiber, but it might not be necessary actually. I would have to check the proof (I will try to do that sometime). I would add that (as you discovered) for a Hartogs type statement you do not need normality and many things can be done for $S_2$ schemes that are usually done for normal ones. The main reason normality is more widely used (besides that it is easier to define and think that one understands it better) is that working with divisors on $S_2$ but not normal schemes has to be done very carefully. See this MO answer for more on this and perhaps this and this for more on Hartogs type questions.

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