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Comments 1 to 20 out of 10600 in reverse chronological order.

\begin{equation*} \DeclareMathOperator\Coim{Coim} \DeclareMathOperator\Coker{Coker} \DeclareMathOperator\Ext{Ext} \DeclareMathOperator\Hom{Hom} \DeclareMathOperator\Im{Im} \DeclareMathOperator\Ker{Ker} \DeclareMathOperator\Mor{Mor} \DeclareMathOperator\Ob{Ob} \DeclareMathOperator\Sh{Sh} \DeclareMathOperator\SheafExt{\mathcal{E}\mathit{xt}} \DeclareMathOperator\SheafHom{\mathcal{H}\mathit{om}} \DeclareMathOperator\Spec{Spec} \newcommand\colim{\mathop{\mathrm{colim}}\nolimits} \newcommand\lim{\mathop{\mathrm{lim}}\nolimits} \newcommand\Qcoh{\mathit{Qcoh}} \newcommand\Sch{\mathit{Sch}} \newcommand\QCohstack{\mathcal{QC}\!\mathit{oh}} \newcommand\Cohstack{\mathcal{C}\!\mathit{oh}} \newcommand\Spacesstack{\mathcal{S}\!\mathit{paces}} \newcommand\Quotfunctor{\mathrm{Quot}} \newcommand\Hilbfunctor{\mathrm{Hilb}} \newcommand\Curvesstack{\mathcal{C}\!\mathit{urves}} \newcommand\Polarizedstack{\mathcal{P}\!\mathit{olarized}} \newcommand\Complexesstack{\mathcal{C}\!\mathit{omplexes}} \newcommand\Pic{\mathop{\mathrm{Pic}}\nolimits} \newcommand\Picardstack{\mathcal{P}\!\mathit{ic}} \newcommand\Picardfunctor{\mathrm{Pic}} \newcommand\Deformationcategory{\mathcal{D}\!\mathit{ef}} \end{equation*}

On left comment #11617 on Section 27.22 in Constructions of Schemes

This is probably because I first looked at EGA I and it wasn't in there (it got introduced in the second edition of EGA I and I prefer to use the first edition). Then I looked in some of the other books in my office and settled on this choice. Your and Grothendieck's choice would have been better (fitting better with the philosphy in the stacks project), but now it's too late as I have found a few references to this section in arXiv papers, at least 1 of which is about to be published.


On left comment #11616 on Section 112.3 in A Guide to the Literature

OK, I replaced the current link on the bibiography page by the archived link you sent as it seems the most stable. However, I do not know if the authors are happy to have this version of their work posted or made public to a wider audience so I inserted a note to that effect. Thanks!


On left comment #11615 on Lemma 14.26.8 in Simplicial Methods

Thanks and fixed here.


On left comment #11614 on Section 17.17 in Sheaves of Modules

Same remark for Lemma 05NJ.


On left comment #11613 on Section 13.21 in Derived Categories

For example one could replace "injective" by "-acyclic" in Definition 13.21.1. Then a different mechanism/property of the situation would be needed to prove the existence. For example, note that in the steps (2), (3) we need something slightly weaker than Lemma 13.18.9. So I think having a collection of objects as in Lemma 13.15.6 would work.


On left comment #11612 on Section 7.6 in Sites and Sheaves

I do not understand your comment, because we always have and this is a covering by definition.


On left comment #11611 on Lemma 10.38.5 in Commutative Algebra

Thanks! Fixed here.


On left comment #11610 on Lemma 13.7.1 in Derived Categories

Sorry for the late realization that you pointed out an actual error in the proof. I've fixed it without adding too much text by choosing the "correct" isomorphisms of with . See this commit.


On Jakob Scholbach left comment #11609 on Lemma 10.119.7 in Commutative Algebra

I think in the very last sentence it should say every nonzero element of can be written as ...


On left comment #11608 on Section 55.1 in Semistable Reduction

Dear Jay, I think the missing part is in Expose I of SGA 7-I, especially in remarque 3.6. The circling back to curves is still true, but it is only using resolution of models of curves over dvrs and not semi-stable reduction. So it is not a loop.


On Alex Scheffelin left comment #11607 on Lemma 20.37.11 in Cohomology of Sheaves

I think using https://stacks.math.columbia.edu/tag/0D60 you can directly get that using that .


On K. F. left comment #11606 on Lemma 10.125.3 in Commutative Algebra

I think there may be a typo in the statement of Lemma 0520.

The conclusion currently reads

Since the left-hand side is an ideal of , shouldn't the right-hand side instead be


On Wolfgang Soergel left comment #11605 on Section 10.20 in Commutative Algebra

I would understand the geometric content slightly differently. Suppose is a finitely generated -module and for an ideal . Then for every prime ideal above and hence , since otherwise would have a simple quotient which necessarily is killed by . So the support of is disjoint to the closed set of prime ideals above . Again by finite generation, the support is the set of prime ideals containing the annihilator . So there are no prime ideals above and , which means their sum is the whole ring . In particular, with and in the annihilator of .


On left comment #11604 on Section 67.3 in Morphisms of Algebraic Spaces

The following result might fit to this section (it is the analogous result to Properties of Algebraic Spaces, Lemma 66.7.1, but for properties of morphisms). It is stated without proof in Olsson's Algebraic Spaces and Stacks, 5.4.3.

Lemma. Let be a property of morphisms of schemes satisfying:

  1. is preserved under any base change, see Schemes, Definition 26.18.3, and

  2. is étale local on the base, see Descent, Definition 35.22.1.

(This is almost like the hypotheses from Algebraic Spaces, Definition 65.5.1 but we require étale locality on the base, rather than fppf locality.) Let be a scheme and let be a representable morphism of algebraic spaces over . The following are equivalent:

  1. For some scheme and surjective étale morphism , the morphism of schemes has property .

  2. For every scheme and every morphism , the morphism of schemes has property . (That is, has as in Algebraic Spaces, Definition 65.5.1.)

Proof. The implication (2) (1) is immediate. For the converse, choose a surjective étale morphism with a scheme such that has and let be a -scheme. Let . That is, every face in this commutative cube is cartesian. Note that every vertex of the cube other than and is a scheme. In the cube diagram, since the top square is cartesian and is preserved under base-change, has . On the other hand, is étale surjective. Thus, since is étale local on the base, we conclude that has , as desired.


On Yuki left comment #11603 on Lemma 10.127.6 in Commutative Algebra

In item (3) of the lemma, -module maps should be -module maps .


On Jonas van der Schaaf left comment #11602 on Lemma 15.8.1 in More on Algebra

Point 5 is "add more here", and should probably be removed.


On Zhenhua Wu left comment #11601 on Lemma 4.31.12 in Categories

The notation here should be


On left comment #11600 on Lemma 29.10.2 in Morphisms of Schemes

In loc. cit. we find a fifth equivalent condition: for every field , there is an algebraically closed field extension of such that the induced map is injective.

Also, in Altman, Kleiman, Introduction to Grothendieck Duality Theory, p. 119, there is yet another additional equivalent condition: for any field and any morphism , the morphism is injective.


On left comment #11599 on Lemma 29.10.2 in Morphisms of Schemes

This result is EGA I, 2nd ed., Ch. I, Proposition 3.7.1.


On Pijush left comment #11598 on Section 42.40 in Chow Homology and Chern Classes

Is the third sentence of the last lemma missing the rank ""?