Projective bundle

Fiber bundle whose fibers are projective spaces

In mathematics, a projective bundle is a fiber bundle whose fibers are projective spaces.

By definition, a scheme X over a Noetherian scheme S is a Pn-bundle if it is locally a projective n-space; i.e., X × S U P U n {\displaystyle X\times _{S}U\simeq \mathbb {P} _{U}^{n}} and transition automorphisms are linear. Over a regular scheme S such as a smooth variety, every projective bundle is of the form P ( E ) {\displaystyle \mathbb {P} (E)} for some vector bundle (locally free sheaf) E.[1]

The projective bundle of a vector bundle

Every vector bundle over a variety X gives a projective bundle by taking the projective spaces of the fibers, but not all projective bundles arise in this way: there is an obstruction in the cohomology group H2(X,O*). To see why, recall that a projective bundle comes equipped with transition functions on double intersections of a suitable open cover. On triple overlaps, any lift of these transition functions satisfies the cocycle condition up to an invertible function. The collection of these functions forms a 2-cocycle which vanishes in H2(X,O*) only if the projective bundle is the projectivization of a vector bundle. In particular, if X is a compact Riemann surface then H2(X,O*)=0, and so this obstruction vanishes.

The projective bundle of a vector bundle E is the same thing as the Grassmann bundle G 1 ( E ) {\displaystyle G_{1}(E)} of 1-planes in E.

The projective bundle P(E) of a vector bundle E is characterized by the universal property that says:[2]

Given a morphism f: TX, to factorize f through the projection map p: P(E) → X is to specify a line subbundle of f*E.

For example, taking f to be p, one gets the line subbundle O(-1) of p*E, called the tautological line bundle on P(E). Moreover, this O(-1) is a universal bundle in the sense that when a line bundle L gives a factorization f = pg, L is the pullback of O(-1) along g. See also Cone#O(1) for a more explicit construction of O(-1).

On P(E), there is a natural exact sequence (called the tautological exact sequence):

0 O P ( E ) ( 1 ) p E Q 0 {\displaystyle 0\to {\mathcal {O}}_{\mathbf {P} (E)}(-1)\to p^{*}E\to Q\to 0}

where Q is called the tautological quotient-bundle.

Let EF be vector bundles (locally free sheaves of finite rank) on X and G = F/E. Let q: P(F) → X be the projection. Then the natural map O(-1) → q*Fq*G is a global section of the sheaf hom Hom(O(-1), q*G) = q* GO(1). Moreover, this natural map vanishes at a point exactly when the point is a line in E; in other words, the zero-locus of this section is P(E).

A particularly useful instance of this construction is when F is the direct sum E ⊕ 1 of E and the trivial line bundle (i.e., the structure sheaf). Then P(E) is a hyperplane in P(E ⊕ 1), called the hyperplane at infinity, and the complement of P(E) can be identified with E. In this way, P(E ⊕ 1) is referred to as the projective completion (or "compactification") of E.

The projective bundle P(E) is stable under twisting E by a line bundle; precisely, given a line bundle L, there is the natural isomorphism:

g : P ( E ) P ( E L ) {\displaystyle g:\mathbf {P} (E){\overset {\sim }{\to }}\mathbf {P} (E\otimes L)}

such that g ( O ( 1 ) ) O ( 1 ) p L . {\displaystyle g^{*}({\mathcal {O}}(-1))\simeq {\mathcal {O}}(-1)\otimes p^{*}L.} [3] (In fact, one gets g by the universal property applied to the line bundle on the right.)

Examples

Many non-trivial examples of projective bundles can be found using fibrations over P 1 {\displaystyle \mathbb {P} ^{1}} such as Lefschetz fibrations. For example, an elliptic K3 surface X {\displaystyle X} is a K3 surface with a fibration

π : X P 1 {\displaystyle \pi :X\to \mathbb {P} ^{1}}

such that the fibers E p {\displaystyle E_{p}} for p P 1 {\displaystyle p\in \mathbb {P} ^{1}} are generically elliptic curves. Because every elliptic curve is a genus 1 curve with a distinguished point, there exists a global section of the fibration. Because of this global section, there exists a model of X {\displaystyle X} giving a morphism to the projective bundle[4]

X P ( O P 1 ( 4 ) O P 1 ( 6 ) O P 1 ) {\displaystyle X\to \mathbb {P} ({\mathcal {O}}_{\mathbb {P} ^{1}}(4)\oplus {\mathcal {O}}_{\mathbb {P} ^{1}}(6)\oplus {\mathcal {O}}_{\mathbb {P} ^{1}})}

defined by the Weierstrass equation

y 2 z + a 1 x y z + a 3 y z 2 = x 3 + a 2 x 2 z + a 4 x z 2 + a 6 z 3 {\displaystyle y^{2}z+a_{1}xyz+a_{3}yz^{2}=x^{3}+a_{2}x^{2}z+a_{4}xz^{2}+a_{6}z^{3}}

where x , y , z {\displaystyle x,y,z} represent the local coordinates of O P 1 ( 4 ) , O P 1 ( 6 ) , O P 1 {\displaystyle {\mathcal {O}}_{\mathbb {P} ^{1}}(4),{\mathcal {O}}_{\mathbb {P} ^{1}}(6),{\mathcal {O}}_{\mathbb {P} ^{1}}} , respectively, and the coefficients

a i H 0 ( P 1 , O P 1 ( 2 i ) ) {\displaystyle a_{i}\in H^{0}(\mathbb {P} ^{1},{\mathcal {O}}_{\mathbb {P} ^{1}}(2i))}

are sections of sheaves on P 1 {\displaystyle \mathbb {P} ^{1}} . Note this equation is well-defined because each term in the Weierstrass equation has total degree 12 {\displaystyle 12} (meaning the degree of the coefficient plus the degree of the monomial. For example, deg ( a 1 x y z ) = 2 + ( 4 + 6 + 0 ) = 12 {\displaystyle {\text{deg}}(a_{1}xyz)=2+(4+6+0)=12} ).

Cohomology ring and Chow group

Let X be a complex smooth projective variety and E a complex vector bundle of rank r on it. Let p: P(E) → X be the projective bundle of E. Then the cohomology ring H*(P(E)) is an algebra over H*(X) through the pullback p*. Then the first Chern class ζ = c1(O(1)) generates H*(P(E)) with the relation

ζ r + c 1 ( E ) ζ r 1 + + c r ( E ) = 0 {\displaystyle \zeta ^{r}+c_{1}(E)\zeta ^{r-1}+\cdots +c_{r}(E)=0}

where ci(E) is the i-th Chern class of E. One interesting feature of this description is that one can define Chern classes as the coefficients in the relation; this is the approach taken by Grothendieck.

Over fields other than the complex field, the same description remains true with Chow ring in place of cohomology ring (still assuming X is smooth). In particular, for Chow groups, there is the direct sum decomposition

A k ( P ( E ) ) = i = 0 r 1 ζ i A k r + 1 + i ( X ) . {\displaystyle A_{k}(\mathbf {P} (E))=\bigoplus _{i=0}^{r-1}\zeta ^{i}A_{k-r+1+i}(X).}

As it turned out, this decomposition remains valid even if X is not smooth nor projective.[5] In contrast, Ak(E) = Ak-r(X), via the Gysin homomorphism, morally because that the fibers of E, the vector spaces, are contractible.

See also

References

  1. ^ Hartshorne 1977, Ch. II, Exercise 7.10. (c).
  2. ^ Hartshorne 1977, Ch. II, Proposition 7.12.
  3. ^ Hartshorne 1977, Ch. II, Lemma 7.9.
  4. ^ Propp, Oron Y. (2019-05-22). "Constructing explicit K3 spectra". arXiv:1810.08953 [math.AT].
  5. ^ Fulton 1998, Theorem 3.3.