Euler sequence: Difference between revisions

Browse history interactively

← Previous edit

Content deleted Content added

VisualWikitext

Revision as of 16:29, 16 April 2022 edit Ebony Jackson (talk \| contribs) Extended confirmed users 1,088 edits Unclutter notation by not writing A everywhere. Use longer arrows to make the terms easier to see. Unclutter further by writing PV instead of P(V). ← Previous edit		Latest revision as of 08:57, 7 November 2023 edit undo Kku (talk \| contribs) Extended confirmed users 113,911 edits m link [pP]ower series
(4 intermediate revisions by 2 users not shown)
Line 1: In [[mathematics]], the '''Euler sequence''' is a particular [[exact sequence]] of [[Sheaf (mathematics)\|sheaves]] on ''n''-dimensional [[projective space]] over a [[ring (mathematics)\|ring]]. It shows that the [[sheaf of relative differentials]] is [[stably isomorphic]] to an <math>(''n~~'' ~~+~~ ~~1)</math>-fold sum of the dual of the Serre [[twisting sheaf]]. The Euler sequence generalizes to that of a [[projective bundle]] as well as a [[Grassmann bundle]] (see the latter article for this generalization.) == Statement == Let <math>\mathbb{P}^n_A</math> be the ''An''-dimensional beprojective space over a commutative ring. ''A''. Let <math>\Omega^1 = \Omega^1_{\mathbb P^n_A/A}</math> be the sheaf of 1-differentials on this space, and so on. The Euler sequence is the following exact sequence of sheaves on <math>\mathbb {P}^n_A</math>: <math display="block"> 0 \longrightarrow \Omega^1 \longrightarrow \mathcal{O}(-1)^{\oplus (n+1)} \longrightarrow \mathcal{O} \longrightarrow 0.</math> ItThe sequence can be constructed by defining a homomorphism <math>S(-1)^{\oplus n+1} \to S, e_i \mapsto x_i</math> with <math>S = A[x_0, \ldots, x_n]</math> and <math>e_i = 1</math> in degree 1, surjective in degrees <math>\geq 1</math>, and checking that locally on the {{<math~~\|''~~>n'' + 1}}</math> standard charts, the kernel is isomorphic to the relative differential module.<ref>Theorem II.8.13 in {{Harvnb\|Hartshorne\|1977}}</ref> ==Geometric interpretation== We assume that ''A'' is a [[field (mathematics)\|field]] ''k''. Line 18 ⟶ 17: where <math>\mathcal T</math> is the [[tangent sheaf]] of <math>\mathbb{P}^n</math>. Let us explain the coordinate-free version of this sequence, on <math>\mathbb {P} V</math> for an <math>(''n''+1)</math>-dimensional [[vector space]] ''V'' over ''k'': :<math>0\longrightarrow \mathcal O_{\mathbb {P} V} \longrightarrow \mathcal O_{\mathbb {P} V}(1)\otimes V \longrightarrow \mathcal T_{\mathbb {P} V} \longrightarrow 0. </math> This sequence is most easily understood by interpreting sections of the central term as 1-homogeneous [[vector field]]s on ''V''. One such section, the [[Euler vector field]], associates to each point <math>v</math> of the variety <math>V</math> the tangent vector <math>v</math>. This vector field is radial in the sense that it vanishes uniformly on 0-homogeneous functions, that is, the functions that are invariant by homothetic rescaling, or "''independent of the radial coordinate''". Line 25 ⟶ 24: A function (defined on some open set) on <math>\mathbb P V</math> gives rise by pull-back to a 0-homogeneous function on ''V'' (again partially defined). We obtain 1-homogeneous vector fields by multiplying the Euler vector field by such functions. This is the definition of the first map, and its injectivity is immediate. The second map is related to the notion of derivation, equivalent to that of vector field. Recall that a vector field on an open set ''U'' of the projective space <math>\mathbb {P} V</math> can be defined as a derivation of the functions defined on this open set. Pulled-back in ''V'', this is equivalent to a derivation on the preimage of ''U'' that preserves 0-homogeneous functions. Any vector field on <math>\mathbb{P} V</math> can be thus obtained, and the defect of injectivity of this mapping consists precisely of the radial vector fields.▼ ~~The second map is related to the notion of derivation, equivalent to that of vector field.~~ ▲Recall that a vector field on an open set ''U'' of the projective space <math>\mathbb P V</math> can be defined as a derivation of the functions defined on this open set. Pulled-back in ''V'', this is equivalent to a derivation on the preimage of ''U'' that preserves 0-homogeneous functions. ~~Any vector field on <math>\mathbb P(V)</math> can be thus obtained, and the defect of injectivity of this mapping consists precisely of the radial vector fields.~~ Therefore the kernel of the second morphism equals the image of the first one. == The canonical line bundle of projective spaces== By taking the highest [[exterior power]], one sees that the [[canonical sheaf]] of a [[Algebraic geometry of projective spaces\|projective space]] is given by <math display="block">\omega_{\mathbb{P}^n_A/A} = \mathcal{O}_{\mathbb{P}^n_A}(-(n+1)).</math> In particular, projective spaces are [[Fano varieties]], because the canonical bundle is anti-[[ample line bundle\|ample]] and this line bundle has no non-zero global sections, so the [[geometric genus]] is 0. This can be found by looking at the Euler sequence and plugging it into the determinant formula<ref>{{Cite book\|last=Vakil\|first=Ravi\|url=http://math.stanford.edu/~vakil/216blog/FOAGnov1817public.pdf\| title=Rising Sea\|location=386\|archive-url=https://web.archive.org/web/20191130195401/http://math.stanford.edu/~vakil/216blog/FOAGnov1817public.pdf\|archive-date=2019-11-30}}</ref> <math display="block">\det(\mathcal{E}) = \det(\mathcal{E}') \otimes \det(\mathcal{E}'')</math> for any short exact sequence of the form <math>0 \to \mathcal{E}' \to \mathcal{E} \to \mathcal{E}''\to 0</math>. == Chern ~~Classes~~ classes== The ~~euler~~Euler sequence can be used to compute the [[Chern class]]es of projective space. Recall that given a short exact sequence of coherent sheaves , <math display="block">0 \to \mathcal{E}' \to \mathcal{E} \to \mathcal{E}''\to 0,</math> we can compute the total ~~chern~~Chern class of <math>\mathcal{E}</math> with the formula <math>c(\mathcal{E}) = c(\mathcal{E}')\cdot c(\mathcal{E}'')</math>.<ref>{{Cite web\|url=https://scholar.harvard.edu/files/joeharris/files/000-final-3264.pdf\|title=3264 and all that\|page=169}}</ref> For example, on <math>\mathbb{P}^2</math> we find<ref>Note that <math>[H]^3 = 0</math> in the ~~chow~~Chow ring for dimension reasons.</ref> <math display="block">\begin{align} c(\Omega^1_{\mathbb{P}^2}) &= \frac{c(\mathcal{O}(-1)^{\oplus (2+1)})}{c(\mathcal{O})} \\ &= (1 - [H])^3 \\ &= 1 - 3[H] + 3[H]^2 - [H]^3 \\ &= 1 - 3[H] + 3[H]^2, \end{align}</math> ~~\end{align}</math>~~ where <math>[H]</math> represents the hyperplane class in the ~~chow~~[[Chow group\|Chow ring]] <math>A^\bullet(\mathbb{P}^2)</math>. Using the exact sequence<ref>{{Cite web\|url=https://www.math.purdue.edu/~arapura/preprints/book-chap17.pdf\|title=Computation of Some Hodge Numbers\| last=Arapura\|first=Donu\| url-status=live\|archive-url=https://web.archive.org/web/20200201234047/https://www.math.purdue.edu/~arapura/preprints/book-chap17.pdf\|archive-date=1 February 2020}}</ref> ~~<math display="block">0 \to \Omega^2 \to \mathcal{O}(-2)^{\oplus 3} \to \Omega^1 \to 0</math> we can again use the total chern class formula to find <math display="block">\begin{align}~~ <math display="block">0 \to \Omega^2 \to \mathcal{O}(-2)^{\oplus 3} \to \Omega^1 \to 0,</math> we can again use the total Chern class formula to find <math display="block">\begin{align} c(\Omega^2) &= \frac{c(\mathcal{O}(-2)^{\oplus 3})}{c(\Omega^1)} \\ &= \frac{(1 - 2[H])^3}{1 - 3[H] + 3[H]^2} \\. \end{align}</math> ~~\end{align}</math> since~~Since we need to invert the polynomial in the denominator, this is equivalent to finding a [[power series]] <math>a([H]) = a_0 + a_1[H] + a_2[H]^2 +a_3[H]^3 + \cdots</math> such that <math>a([H])c(\Omega^1) = 1</math>. == Notes == Line 50 ⟶ 54: == References == * {{Hartshorne AG}} * {{Citation \| last1=Rubei \| first1=Elena \| title=Algebraic Geometry, a concise dictionary \| publisher=[[De Gruyter\|Walter De Gruyter]] \| location=Berlin/Boston \| isbn=978-3-11-031622-3 \| year=2014\|ref=none}} [[Category:Algebraic geometry]]