Let $X$ be a topological space and $U\subset X$ an open subset. Let's work in the category of sheaves of abelian groups on $X$. Consider the constant sheaf on $U$, $\mathbb{Z}_U$, given by $\mathbb{Z}_U(V)=\{\text{continuous maps }U\cap V\rightarrow \mathbb Z\}$, where $\mathbb Z$ is given the discrete topology. I've been struggling to derive from Yoneda's lemma the formula $\hom(\mathbb{Z}_U,F)=F(U)$. Is this a consequence of Yoneda? If so, how? If it doesn't follow from Yoneda, is it true at all? If not, how can one compute $\hom(\mathbb{Z}_U,\mathbb{Z}_V)?$
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asked Mar 8, 2013 at 11:53
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$\begingroup$ Yes, it is a formal consequence of Yoneda and the fact that sheafification and the free abelian group functor are left adjoints. $\endgroup$– Zhen LinCommented Mar 8, 2013 at 13:00
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$\begingroup$ Actually, the formulation of the question is incorrect, which led to the two different answers. You write that $\mathbb Z_U$ is a sheaf on $U$, while $F$ is a sheaf on $X$; so $\mathop{\rm hom}(\mathbb Z_U,F)$ does not make sense. You must either restrict $F$ to $U$ or extend $\mathbb Z_U$ to $X$. In the first case, the answer is yes (Zhen Lin's comment), and in the second it depends on the choice of an extension (direct image or extension by zero). $\endgroup$– ACLCommented Apr 24, 2015 at 8:08
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3 Answers
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This is not true; for example, take $X = \mathbb R^2$, $U = \mathbb R^2 \smallsetminus \{(0,0)\}$. Then your $\mathbb Z_U$ coincides with $\mathbb Z_X$, and $Hom(\mathbb Z_U, F)$ is $F(X)$, not $F(U)$.
For the formula to hold you have to take as $\mathbb Z_U$ the extension of the constant sheaf by $0$, which is a very different animal.
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$\begingroup$ @Angelo, thanks! Indeed you're right, I must have confused both things, what would then be a direct description of $\mathbb{Z}_U(V)$ for the right $\mathbb{Z}_U$ you suggests? (The extension of the constant sheaf $\mathbb{Z}$ on $U$ to $0$ in the rest). $\endgroup$ Commented Mar 8, 2013 at 15:25
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1$\begingroup$ Locally constant function $V \to \mathbb Z$ that are zero on $V\smallsetminus U$. $\endgroup$– AngeloCommented Mar 8, 2013 at 15:39
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See [Tamme, Introduction to étale cohomology], p. 31, Remark (2.1.3).
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$\begingroup$ And the sheafification of Tamme's $Z_U$ is my $\mathbb{Z}_U$ above, isn't it? $\endgroup$ Commented Mar 8, 2013 at 12:55
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1$\begingroup$ You have to distinguish $j_!\mathbf{Z}$ from your $\mathbf{Z}_U$ above. $\endgroup$– user19475Commented Mar 8, 2013 at 13:33
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1$\begingroup$ @Timo, thanks! Is there any easy direct description of the values $(j_!\mathbb{Z})(V)$? $\endgroup$ Commented Mar 8, 2013 at 15:30
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1$\begingroup$ @Fernando: See [Hartshorne, Algebraic Geometry] Exercise II.1.19 ("Extending a sheaf by zero"). $\endgroup$– user19475Commented Mar 8, 2013 at 15:35
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Pierre Schapira has some very nice, and more elementary notes that could help you.
answered Mar 8, 2013 at 13:03