Difference between revisions of "Flabby sheaf"
From Encyclopedia of Mathematics
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| − | A sheaf | + | {{MSC|14}} |
| + | {{TEX|done}} | ||
| + | |||
| + | A ''flabby sheaf" is | ||
| + | a sheaf $F$ of sets over a topological space $X$ such that for any set $U$ open in $X$ the restriction mapping $F(X)\to F(U)$ is surjective. Examples of such sheaves include the sheaf of germs of all (not necessarily continuous) sections of a | ||
| + | [[Fibre space|fibre space]] with base $X$, the sheaf of germs of divisors (cf. | ||
| + | [[Divisor|Divisor]]), and a prime sheaf $F$ over an irreducible algebraic variety. Flabbiness of a sheaf $F$ is a local property (i.e. a flabby sheaf induces a flabby sheaf on any open set). A quotient sheaf of a flabby sheaf by a flabby sheaf is itself a flabby sheaf. The image of a flabby sheaf under a continuous mapping is a flabby sheaf. If $X$ is paracompact, a flabby sheaf is a | ||
| + | [[Soft sheaf|soft sheaf]], i.e. any section of $F$ over a closed set can be extended to the entire space $X$. | ||
Let | Let | ||
| − | + | $$0\to F^0\to F^1\to \cdots$$ | |
| − | + | be an exact sequence of flabby sheaves of Abelian groups. Then, for any family $\Phi$ of supports, the corresponding sequence of sections (the supports of which belong to $\Phi$) | |
| − | be an exact sequence of flabby sheaves of Abelian groups. Then, for any family | ||
| − | |||
| − | |||
| − | is exact, i.e. | + | $$0\to\def\G{\Gamma}\G_\Phi(F^0)\to\G_\Phi(F^1)\to\cdots$$ |
| + | is exact, i.e. $F\mapsto \G_\Phi(F)$ is a left-exact functor. | ||
====Comments==== | ====Comments==== | ||
| − | Flabby sheaves are used for resolutions in the construction of sheaf cohomology (i.e. [[Cohomology|cohomology]] with values in a sheaf) in algebraic geometry and topology, | + | Flabby sheaves are used for resolutions in the construction of sheaf cohomology (i.e. |
| + | [[Cohomology|cohomology]] with values in a sheaf) in algebraic geometry and topology, | ||
| + | {{Cite|Mi}}. | ||
====References==== | ====References==== | ||
| − | + | {| | |
| + | |- | ||
| + | |valign="top"|{{Ref|Mi}}||valign="top"| J.S. Milne, "Etale cohomology", Princeton Univ. Press (1980) {{MR|0559531}} {{ZBL|0433.14012}} | ||
| + | |- | ||
| + | |} | ||
Revision as of 21:52, 24 November 2013
2020 Mathematics Subject Classification: Primary: 14-XX [MSN][ZBL]
A flabby sheaf" is a sheaf $F$ of sets over a topological space $X$ such that for any set $U$ open in $X$ the restriction mapping $F(X)\to F(U)$ is surjective. Examples of such sheaves include the sheaf of germs of all (not necessarily continuous) sections of a fibre space with base $X$, the sheaf of germs of divisors (cf. Divisor), and a prime sheaf $F$ over an irreducible algebraic variety. Flabbiness of a sheaf $F$ is a local property (i.e. a flabby sheaf induces a flabby sheaf on any open set). A quotient sheaf of a flabby sheaf by a flabby sheaf is itself a flabby sheaf. The image of a flabby sheaf under a continuous mapping is a flabby sheaf. If $X$ is paracompact, a flabby sheaf is a soft sheaf, i.e. any section of $F$ over a closed set can be extended to the entire space $X$.
Let
$$0\to F^0\to F^1\to \cdots$$ be an exact sequence of flabby sheaves of Abelian groups. Then, for any family $\Phi$ of supports, the corresponding sequence of sections (the supports of which belong to $\Phi$)
$$0\to\def\G{\Gamma}\G_\Phi(F^0)\to\G_\Phi(F^1)\to\cdots$$ is exact, i.e. $F\mapsto \G_\Phi(F)$ is a left-exact functor.
Comments
Flabby sheaves are used for resolutions in the construction of sheaf cohomology (i.e. cohomology with values in a sheaf) in algebraic geometry and topology, [Mi].
References
| [Mi] | J.S. Milne, "Etale cohomology", Princeton Univ. Press (1980) MR0559531 Zbl 0433.14012 |
How to Cite This Entry:
Flabby sheaf. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Flabby_sheaf&oldid=30770
Flabby sheaf. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Flabby_sheaf&oldid=30770
This article was adapted from an original article by M.I. Voitsekhovskii (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article