Quintic threefold

In mathematics, a quintic threefold is a 3-dimensional hypersurface of degree 5 in 4-dimensional projective space ${\displaystyle {\mathbb{P}}^4}$. Non-singular quintic threefolds are Calabi–Yau manifolds.

The Hodge diamond of a non-singular quintic 3-fold is Template:Hodge diamond

Mathematician Robbert Dijkgraaf said "One number which every algebraic geometer knows is the number 2,875 because obviously, that is the number of lines on a quintic."^[1]

A quintic threefold is a special class of Calabi–Yau manifolds defined by a degree ${\displaystyle 5}$ projective variety in ${\displaystyle {\mathbb{P}}^4}$. Many examples are constructed as hypersurfaces in ${\displaystyle {\mathbb{P}}^4}$, or complete intersections lying in ${\displaystyle {\mathbb{P}}^4}$, or as a smooth variety resolving the singularities of another variety. As a set, a Calabi-Yau manifold is$${\displaystyle X=\{x=[x_0:x_1:x_2:x_3:x_4]\in {ℂ\mathbb{P}}^4:p(x)=0\}}$$where ${\displaystyle p(x)}$ is a degree ${\displaystyle 5}$ homogeneous polynomial. One of the most studied examples is from the polynomial$${\displaystyle p(x)=x_0^5+x_1^5+x_2^5+x_3^5+x_4^5}$$called a Fermat polynomial. Proving that such a polynomial defines a Calabi-Yau requires some more tools, like the Adjunction formula and conditions for smoothness.

Recall that a homogeneous polynomial ${\displaystyle f\in \mathrm{\Gamma }({\mathbb{P}}^4,𝒪(d))}$ (where ${\displaystyle 𝒪(d)}$ is the Serre-twist of the hyperplane line bundle) defines a projective variety, or projective scheme, ${\displaystyle X}$, from the algebra$${\displaystyle \frac{k[x_0,\dots ,x_4]}{(f)}}$$where ${\displaystyle k}$ is a field, such as ${\displaystyle ℂ}$. Then, using the adjunction formula to compute its canonical bundle, we have$${\displaystyle \begin{array}{cc}{\mathrm{\Omega }}_X^3& ={\omega }_X\\ & ={\omega }_{{\mathbb{P}}^4}\otimes 𝒪(d)\\ & \cong 𝒪(-(4+1))\otimes 𝒪(d)\\ & \cong 𝒪(d-5)\end{array}}$$hence in order for the variety to be Calabi-Yau, meaning it has a trivial canonical bundle, its degree must be ${\displaystyle 5}$. It is then a Calabi-Yau manifold if in addition this variety is smooth. This can be checked by looking at the zeros of the polynomials$${\displaystyle {\partial }_{0}f,\dots ,{\partial }_{4}f}$$and making sure the set$${\displaystyle \{x=[x_0:\cdots :x_4]|f(x)={\partial }_{0}f(x)=\cdots ={\partial }_{4}f(x)=0\}}$$is empty.

One of the easiest examples to check of a Calabi-Yau manifold is given by the Fermat quintic threefold, which is defined by the vanishing locus of the polynomial$${\displaystyle f=x_0^5+x_1^5+x_2^5+x_3^5+x_4^5}$$Computing the partial derivatives of ${\displaystyle f}$ gives the four polynomials$${\displaystyle \begin{array}{c}{\partial }_{0}f=5x_0^4\\ {\partial }_{1}f=5x_1^4\\ {\partial }_{2}f=5x_2^4\\ {\partial }_{3}f=5x_3^4\\ {\partial }_{4}f=5x_4^4\\ \end{array}}$$Since the only points where they vanish is given by the coordinate axes in ${\displaystyle {\mathbb{P}}^4}$, the vanishing locus is empty since ${\displaystyle [0:0:0:0:0]}$ is not a point in ${\displaystyle {\mathbb{P}}^4}$.

Another application of the quintic threefold is in the study of the infinitesimal generalized Hodge conjecture where this difficult problem can be solved in this case.^[2] In fact, all of the lines on this hypersurface can be found explicitly.

Another popular class of examples of quintic three-folds, studied in many contexts, is the Dwork family. One popular study of such a family is from Candelas, De La Ossa, Green, and Parkes,^[3] when they discovered mirror symmetry. This is given by the family^{[4] pages 123-125}$${\displaystyle f_{\psi }=x_0^5+x_1^5+x_2^5+x_3^5+x_4^5-5\psi x_0{x}_1{x}_2{x}_3{x}_4}$$where ${\displaystyle \psi }$ is a single parameter not equal to a 5-th root of unity. This can be found by computing the partial derivates of ${\displaystyle f_{\psi }}$ and evaluating their zeros. The partial derivates are given by$${\displaystyle \begin{array}{c}{\partial }_0{f}_{\psi }=5x_0^4-5\psi x_1{x}_2{x}_3{x}_4\\ {\partial }_1{f}_{\psi }=5x_1^4-5\psi x_0{x}_2{x}_3{x}_4\\ {\partial }_2{f}_{\psi }=5x_2^4-5\psi x_0{x}_1{x}_3{x}_4\\ {\partial }_3{f}_{\psi }=5x_3^4-5\psi x_0{x}_1{x}_2{x}_4\\ {\partial }_4{f}_{\psi }=5x_4^4-5\psi x_0{x}_1{x}_2{x}_3\\ \end{array}}$$At a point where the partial derivatives are all zero, this gives the relation ${\displaystyle x_i^5=\psi x_0{x}_1{x}_2{x}_3{x}_4}$. For example, in ${\displaystyle {\partial }_0{f}_{\psi }}$ we get$${\displaystyle \begin{array}{cc}5x_0^4& =5\psi x_1{x}_2{x}_3{x}_4\\ x_0^4& =\psi x_1{x}_2{x}_3{x}_4\\ x_0^5& =\psi x_0{x}_1{x}_2{x}_3{x}_4\end{array}}$$by dividing out the ${\displaystyle 5}$ and multiplying each side by ${\displaystyle x_0}$. From multiplying these families of equations ${\displaystyle x_i^5=\psi x_0{x}_1{x}_2{x}_3{x}_4}$ together we have the relation$${\displaystyle \prod x_i^5={\psi }^5\prod x_i^5}$$showing a solution is either given by an ${\displaystyle x_i=0}$ or ${\displaystyle {\psi }^5=1}$. But in the first case, these give a smooth sublocus since the varying term in ${\displaystyle f_{\psi }}$ vanishes, so a singular point must lie in ${\displaystyle {\psi }^5=1}$. Given such a ${\displaystyle \psi }$, the singular points are then of the form$${\displaystyle [{\mu }_5^{a_0}:\cdots :{\mu }_5^{a_4}]}$$ such that $${\displaystyle {\mu }_5^{\sum a_i}={\psi }^{-1}}$$where ${\displaystyle {\mu }_5=e^{2\pi i/5}}$. For example, the point$${\displaystyle [{\mu }_5^4:{\mu }_5^{-1}:{\mu }_5^{-1}:{\mu }_5^{-1}:{\mu }_5^{-1}]}$$is a solution of both ${\displaystyle f_1}$ and its partial derivatives since ${\displaystyle ({\mu }_5^i{)}^5=({\mu }_5^5{)}^i=1^i=1}$, and ${\displaystyle \psi =1}$.

• Barth–Nieto quintic
• Consani–Scholten quintic

Computing the number of rational curves of degree ${\displaystyle 1}$ can be computed explicitly using Schubert calculus. Let ${\displaystyle T^{*}}$ be the rank ${\displaystyle 2}$ vector bundle on the Grassmannian ${\displaystyle G(2,5)}$ of ${\displaystyle 2}$-planes in some rank ${\displaystyle 5}$ vector space. Projectivizing ${\displaystyle G(2,5)}$ to ${\displaystyle 𝔾(1,4)}$ gives the projective Grassmannian of degree ${\displaystyle 1}$ lines in ${\displaystyle {\mathbb{P}}^4}$ and ${\displaystyle T^{*}}$ descends to a vector bundle on this projective Grassmannian. Its total Chern class is$${\displaystyle c(T^{*})=1+{\sigma }_1+{\sigma }_{1,1}}$$in the Chow ring ${\displaystyle A^{\bullet }(𝔾(1,4))}$. Now, a section ${\displaystyle l\in \mathrm{\Gamma }(𝔾(1,4),T^{*})}$ of the bundle corresponds to a linear homogeneous polynomial, ${\displaystyle \tilde{l}\in \mathrm{\Gamma }({\mathbb{P}}^4,𝒪(1))}$, so a section of ${\displaystyle {\text{Sym}}^5(T^{*})}$ corresponds to a quintic polynomial, a section of ${\displaystyle \mathrm{\Gamma }({\mathbb{P}}^4,𝒪(5))}$. Then, in order to calculate the number of lines on a generic quintic threefold, it suffices to compute the integral^[5]$${\displaystyle \underset{𝔾(1,4)}{\int }c({\text{Sym}}^5(T^{*}))=2875}$$This can be done by using the splitting principle. Since$${\displaystyle \begin{array}{cc}c(T^{*})& =(1+\alpha )(1+\beta )\\ & =1+(\alpha +\beta )+\alpha \beta \end{array}}$$and for a dimension ${\displaystyle 2}$ vector space, ${\displaystyle V=V_1\oplus V_2}$,$${\displaystyle {\text{Sym}}^5(V)={\displaystyle \underset{i=0}{\overset{5}{⨁}}}(V_1^{\otimes 5-i}\otimes V_2^{\otimes i})}$$so the total Chern class of ${\displaystyle {\text{Sym}}^5(T^{*})}$ is given by the product$${\displaystyle c({\text{Sym}}^5(T^{*}))={\displaystyle \prod _{i=0}^5}(1+(5-i)\alpha +i\beta )}$$Then, the Euler class, or the top class is$${\displaystyle 5\alpha (4\alpha +\beta )(3\alpha +2\beta )(2\alpha +3\beta )(\alpha +4\beta )5\beta }$$expanding this out in terms of the original Chern classes gives$${\displaystyle \begin{array}{cc}{c}_6({\text{Sym}}^5(T^{*}))& =25{\sigma }_{1,1}(4{\sigma }_1^2+9{\sigma }_{1,1})(6{\sigma }_1^2+{\sigma }_{1,1})\\ & =(100{\sigma }_{3,1}+100{\sigma }_{2,2}+225{\sigma }_{2,2})(6{\sigma }_1^2+{\sigma }_{1,1})\\ & =(100{\sigma }_{3,1}+325{\sigma }_{2,2})(6{\sigma }_1^2+{\sigma }_{1,1})\\ & =600{\sigma }_{3,3}+2275{\sigma }_{3,3}\\ & =2875{\sigma }_{3,3}\end{array}}$$using relations implied by Pieri's formula, including ${\displaystyle {\sigma }_1^2={\sigma }_2+{\sigma }_{1,1}}$, ${\displaystyle {\sigma }_{1,1}\cdot {\sigma }_1^2={\sigma }_{3,1}+{\sigma }_{2,2}}$, ${\displaystyle {\sigma }_{1,1}^2={\sigma }_{2,2}}$.

Template:Harvs conjectured that the number of rational curves of a given degree on a generic quintic threefold is finite. (Some smooth but non-generic quintic threefolds have infinite families of lines on them.) This was verified for degrees up to 7 by Template:Harvs who also calculated the number 609250 of degree 2 rational curves. Template:Harvs conjectured a general formula for the virtual number of rational curves of any degree, which was proved by Template:Harvtxt (the fact that the virtual number equals the actual number relies on confirmation of Clemens' conjecture, currently known for degree at most 11 Template:Harvtxt). The number of rational curves of various degrees on a generic quintic threefold is given by

2875, 609250, 317206375, 242467530000, ...Template:OEIS.

Since the generic quintic threefold is a Calabi–Yau threefold and the moduli space of rational curves of a given degree is a discrete, finite set (hence compact), these have well-defined Donaldson–Thomas invariants (the "virtual number of points"); at least for degree 1 and 2, these agree with the actual number of points.

• Enumerative geometry

• Mirror symmetry (string theory)
• Gromov–Witten invariant
• Jacobian ideal - gives an explicit basis for the Hodge-decomposition
• Deformation theory
• Hodge structure
• Schubert calculus - techniques for determining the number of lines on a quintic threefold

Template:Reflist

• Template:Citation
• Template:Citation
• Template:Citation
• Template:Citation
• Template:Citation
• Template:Citation
• Template:Citation
• Template:Citation