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Jacobian ideal

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In mathematics, the Jacobian ideal or gradient ideal is the ideal generated by the Jacobian of a function or function germ. Let O ( x 1 , , x n ) {\displaystyle {\mathcal {O}}(x_{1},\ldots ,x_{n})} denote the ring of smooth functions in n {\displaystyle n} variables and f {\displaystyle f} a function in the ring. The Jacobian ideal of f {\displaystyle f} is

J f := f x 1 , , f x n . {\displaystyle J_{f}:=\left\langle {\frac {\partial f}{\partial x_{1}}},\ldots ,{\frac {\partial f}{\partial x_{n}}}\right\rangle .}

Relation to deformation theory

In deformation theory, the deformations of a hypersurface given by a polynomial f {\displaystyle f} is classified by the ring C [ x 1 , , x n ] ( f ) + J f . {\displaystyle {\frac {\mathbb {C} }{(f)+J_{f}}}.} This is shown using the Kodaira–Spencer map.

Relation to Hodge theory

In Hodge theory, there are objects called real Hodge structures which are the data of a real vector space H R {\displaystyle H_{\mathbb {R} }} and an increasing filtration F {\displaystyle F^{\bullet }} of H C = H R R C {\displaystyle H_{\mathbb {C} }=H_{\mathbb {R} }\otimes _{\mathbb {R} }\mathbb {C} } satisfying a list of compatibility structures. For a smooth projective variety X {\displaystyle X} there is a canonical Hodge structure.

Statement for degree d hypersurfaces

In the special case X {\displaystyle X} is defined by a homogeneous degree d {\displaystyle d} polynomial f Γ ( P n + 1 , O ( d ) ) {\displaystyle f\in \Gamma (\mathbb {P} ^{n+1},{\mathcal {O}}(d))} this Hodge structure can be understood completely from the Jacobian ideal. For its graded-pieces, this is given by the map C [ Z 0 , , Z n ] ( d ( n 1 + p ) ( n + 2 ) ) F p H n ( X , C ) F p + 1 H n ( X , C ) {\displaystyle \mathbb {C} ^{(d(n-1+p)-(n+2))}\to {\frac {F^{p}H^{n}(X,\mathbb {C} )}{F^{p+1}H^{n}(X,\mathbb {C} )}}} which is surjective on the primitive cohomology, denoted Prim p , n p ( X ) {\displaystyle {\text{Prim}}^{p,n-p}(X)} and has the kernel J f {\displaystyle J_{f}} . Note the primitive cohomology classes are the classes of X {\displaystyle X} which do not come from P n + 1 {\displaystyle \mathbb {P} ^{n+1}} , which is just the Lefschetz class [ L ] n = c 1 ( O ( 1 ) ) d {\displaystyle ^{n}=c_{1}({\mathcal {O}}(1))^{d}} .

Sketch of proof

Reduction to residue map

For X P n + 1 {\displaystyle X\subset \mathbb {P} ^{n+1}} there is an associated short exact sequence of complexes 0 Ω P n + 1 Ω P n + 1 ( log X ) r e s Ω X [ 1 ] 0 {\displaystyle 0\to \Omega _{\mathbb {P} ^{n+1}}^{\bullet }\to \Omega _{\mathbb {P} ^{n+1}}^{\bullet }(\log X)\xrightarrow {res} \Omega _{X}^{\bullet }\to 0} where the middle complex is the complex of sheaves of logarithmic forms and the right-hand map is the residue map. This has an associated long exact sequence in cohomology. From the Lefschetz hyperplane theorem there is only one interesting cohomology group of X {\displaystyle X} , which is H n ( X ; C ) = H n ( X ; Ω X ) {\displaystyle H^{n}(X;\mathbb {C} )=\mathbb {H} ^{n}(X;\Omega _{X}^{\bullet })} . From the long exact sequence of this short exact sequence, there the induced residue map H n + 1 ( P n + 1 , Ω P n + 1 ( log X ) ) H n + 1 ( P n + 1 , Ω X [ 1 ] ) {\displaystyle \mathbb {H} ^{n+1}\left(\mathbb {P} ^{n+1},\Omega _{\mathbb {P} ^{n+1}}^{\bullet }(\log X)\right)\to \mathbb {H} ^{n+1}(\mathbb {P} ^{n+1},\Omega _{X}^{\bullet })} where the right hand side is equal to H n ( P n + 1 , Ω X ) {\displaystyle \mathbb {H} ^{n}(\mathbb {P} ^{n+1},\Omega _{X}^{\bullet })} , which is isomorphic to H n ( X ; Ω X ) {\displaystyle \mathbb {H} ^{n}(X;\Omega _{X}^{\bullet })} . Also, there is an isomorphism H d R n + 1 ( P n + 1 X ) H n + 1 ( P n + 1 ; Ω P n + 1 ( log X ) ) {\displaystyle H_{dR}^{n+1}(\mathbb {P} ^{n+1}-X)\cong \mathbb {H} ^{n+1}\left(\mathbb {P} ^{n+1};\Omega _{\mathbb {P} ^{n+1}}^{\bullet }(\log X)\right)} Through these isomorphisms there is an induced residue map r e s : H d R n + 1 ( P n + 1 X ) H n ( X ; C ) {\displaystyle res:H_{dR}^{n+1}(\mathbb {P} ^{n+1}-X)\to H^{n}(X;\mathbb {C} )} which is injective, and surjective on primitive cohomology. Also, there is the Hodge decomposition H d R n + 1 ( P n + 1 X ) p + q = n + 1 H q ( Ω P p ( log X ) ) {\displaystyle H_{dR}^{n+1}(\mathbb {P} ^{n+1}-X)\cong \bigoplus _{p+q=n+1}H^{q}(\Omega _{\mathbb {P} }^{p}(\log X))} and H q ( Ω P p ( log X ) ) Prim p 1 , q ( X ) {\displaystyle H^{q}(\Omega _{\mathbb {P} }^{p}(\log X))\cong {\text{Prim}}^{p-1,q}(X)} .

Computation of de Rham cohomology group

In turns out the de Rham cohomology group H d R n + 1 ( P n + 1 X ) {\displaystyle H_{dR}^{n+1}(\mathbb {P} ^{n+1}-X)} is much more tractable and has an explicit description in terms of polynomials. The F p {\displaystyle F^{p}} part is spanned by the meromorphic forms having poles of order n p + 1 {\displaystyle \leq n-p+1} which surjects onto the F p {\displaystyle F^{p}} part of Prim n ( X ) {\displaystyle {\text{Prim}}^{n}(X)} . This comes from the reduction isomorphism F p + 1 H d R n + 1 ( P n + 1 X ; C ) Γ ( Ω P n + 1 ( n p + 1 ) ) d Γ ( Ω P n + 1 ( n p ) ) {\displaystyle F^{p+1}H_{dR}^{n+1}(\mathbb {P} ^{n+1}-X;\mathbb {C} )\cong {\frac {\Gamma (\Omega _{\mathbb {P} ^{n+1}}(n-p+1))}{d\Gamma (\Omega _{\mathbb {P} ^{n+1}}(n-p))}}} Using the canonical ( n + 1 ) {\displaystyle (n+1)} -form Ω = j = 0 n ( 1 ) j Z j d Z 0 d Z j ^ d Z n + 1 {\displaystyle \Omega =\sum _{j=0}^{n}(-1)^{j}Z_{j}dZ_{0}\wedge \cdots \wedge {\hat {dZ_{j}}}\wedge \cdots \wedge dZ_{n+1}} on P n + 1 {\displaystyle \mathbb {P} ^{n+1}} where the d Z j ^ {\displaystyle {\hat {dZ_{j}}}} denotes the deletion from the index, these meromorphic differential forms look like A f n p + 1 Ω {\displaystyle {\frac {A}{f^{n-p+1}}}\Omega } where deg ( A ) = ( n p + 1 ) deg ( f ) deg ( Ω ) = ( n p + 1 ) d ( n + 2 ) = d ( n p + 1 ) ( n + 2 ) {\displaystyle {\begin{aligned}{\text{deg}}(A)&=(n-p+1)\cdot {\text{deg}}(f)-{\text{deg}}(\Omega )\\&=(n-p+1)\cdot d-(n+2)\\&=d(n-p+1)-(n+2)\end{aligned}}} Finally, it turns out the kernel is of all polynomials of the form A + f B {\displaystyle A'+fB} where A J f {\displaystyle A'\in J_{f}} . Note the Euler identity f = Z j f Z j {\displaystyle f=\sum Z_{j}{\frac {\partial f}{\partial Z_{j}}}} shows f J f {\displaystyle f\in J_{f}} .

References

  1. ^ José Bertin (2002). Introduction to Hodge theory. Providence, R.I.: American Mathematical Society. pp. 199–205. ISBN 0-8218-2040-0. OCLC 48892689.

See also

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