Moduli stack of elliptic curves: Difference between revisions

In mathematics, the moduli stack of elliptic curves, denoted as ${\displaystyle {ℳ}_{1,1}}$ or ${\displaystyle {ℳ}_{\mathrm{e}\mathrm{l}\mathrm{l}}}$, is an algebraic stack over ${\displaystyle \text{Spec}(\mathbb{Z})}$ classifying elliptic curves. Note that it is a special case of the moduli stack of algebraic curves ${\displaystyle {ℳ}_{g,n}}$. In particular its points with values in some field correspond to elliptic curves over the field, and more generally morphisms from a scheme ${\displaystyle S}$ to it correspond to elliptic curves over ${\displaystyle S}$. The construction of this space spans over a century because of the various generalizations of elliptic curves as the field has developed. All of these generalizations are contained in ${\displaystyle {ℳ}_{1,1}}$.

The moduli stack of elliptic curves is a smooth separated Deligne–Mumford stack of finite type over ${\displaystyle \text{Spec}(\mathbb{Z})}$, but is not a scheme as elliptic curves have non-trivial automorphisms.

There is a proper morphism of ${\displaystyle {ℳ}_{1,1}}$ to the affine line, the coarse moduli space of elliptic curves, given by the j-invariant of an elliptic curve.

It is a classical observation that every elliptic curve over ${\displaystyle ℂ}$ is classified by its periods. Given a basis for its integral homology ${\displaystyle \alpha ,\beta \in H_1(E,\mathbb{Z})}$ and a global holomorphic differential form ${\displaystyle \omega \in \mathrm{\Gamma }(E,{\mathrm{\Omega }}_E^1)}$ (which exists since it is smooth and the dimension of the space of such differentials is equal to the genus, 1), the integrals$${\displaystyle \left[\begin{array}{cc}\underset{\alpha }{\int }\omega & \underset{\beta }{\int }\omega \end{array}\right]=\left[\begin{array}{cc}{\omega }_1& {\omega }_2\end{array}\right]}$$give the generators for a ${\displaystyle \mathbb{Z}}$-lattice of rank 2 inside of ${\displaystyle ℂ}$^{[1] pg 158}. Conversely, given an integral lattice ${\displaystyle \mathrm{\Lambda }}$ of rank ${\displaystyle 2}$ inside of ${\displaystyle ℂ}$, there is an embedding of the complex torus ${\displaystyle E_{\mathrm{\Lambda }}=ℂ/\mathrm{\Lambda }}$ into ${\displaystyle {\mathbb{P}}^2}$ from the Weierstrass P function^{[1] pg 165}. This isomorphic correspondence ${\displaystyle \varphi :ℂ/\mathrm{\Lambda }\to E(ℂ)}$ is given by$${\displaystyle z\mapsto [\mathrm{\wp }(z,\mathrm{\Lambda }),{\mathrm{\wp }}^{\prime }(z,\mathrm{\Lambda }),1]\in {\mathbb{P}}^2(ℂ)}$$and holds up to homothety of the lattice ${\displaystyle \mathrm{\Lambda }}$, which is the equivalence relation$${\displaystyle z\mathrm{\Lambda }\sim \mathrm{\Lambda }\text{for}z\in ℂ\setminus \{0\}}$$It is standard to then write the lattice in the form ${\displaystyle \mathbb{Z}\oplus \mathbb{Z}\cdot \tau }$ for ${\displaystyle \tau \in 𝔥}$, an element of the upper half-plane, since the lattice ${\displaystyle \mathrm{\Lambda }}$ could be multiplied by ${\displaystyle {\omega }_1^{-1}}$, and ${\displaystyle \tau ,-\tau }$ both generate the same sublattice. Then, the upper half-plane gives a parameter space of all elliptic curves over ${\displaystyle ℂ}$. There is an additional equivalence of curves given by the action of the$${\displaystyle {\text{SL}}_2(\mathbb{Z})=\{\left(\begin{array}{cc}a& b\\ c& d\end{array}\right)\in {\text{Mat}}_{2,2}(\mathbb{Z}):ad-bc=1\}}$$where an elliptic curve defined by the lattice ${\displaystyle \mathbb{Z}\oplus \mathbb{Z}\cdot \tau }$ is isomorphic to curves defined by the lattice ${\displaystyle \mathbb{Z}\oplus \mathbb{Z}\cdot {\tau }^{\prime }}$ given by the modular action$${\displaystyle \begin{array}{cc}\left(\begin{array}{cc}a& b\\ c& d\end{array}\right)\cdot \tau & =\frac{a\tau +b}{c\tau +d}\\ & ={\tau }^{\prime }\end{array}}$$Then, the moduli stack of elliptic curves over ${\displaystyle ℂ}$ is given by the stack quotient$${\displaystyle {ℳ}_{1,1}\cong [{\text{SL}}_2(\mathbb{Z})\mathrm{\setminus }𝔥]}$$Note some authors construct this moduli space by instead using the action of the Modular group ${\displaystyle {\text{PSL}}_2(\mathbb{Z})={\text{SL}}_2(\mathbb{Z})/\{\pm I\}}$. In this case, the points in ${\displaystyle {ℳ}_{1,1}}$ having only trivial stabilizers are dense.

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Generically, the points in ${\displaystyle {ℳ}_{1,1}}$ are isomorphic to the classifying stack ${\displaystyle B(\mathbb{Z}/2)}$ since every elliptic curve corresponds to a double cover of ${\displaystyle {\mathbb{P}}^1}$, so the ${\displaystyle \mathbb{Z}/2}$-action on the point corresponds to the involution of these two branches of the covering. There are a few special points^{[2] pg 10-11} corresponding to elliptic curves with ${\displaystyle j}$-invariant equal to ${\displaystyle 1728}$ and ${\displaystyle 0}$ where the automorphism groups are of order 4, 6, respectively^{[3] pg 170}. One point in the Fundamental domain with stabilizer of order ${\displaystyle 4}$ corresponds to ${\displaystyle \tau =i}$, and the points corresponding to the stabilizer of order ${\displaystyle 6}$ correspond to ${\displaystyle \tau =e^{2\pi i/3},e^{\pi i/3}}$^{[4]pg 78}.

Given a plane curve by its Weierstrass equation$${\displaystyle y^2=x^3+ax+b}$$and a solution ${\displaystyle (t,s)}$, generically for j-invariant ${\displaystyle j\ne 0,1728}$, there is the ${\displaystyle \mathbb{Z}/2}$-involution sending ${\displaystyle (t,s)\mapsto (t,-s)}$. In the special case of a curve with complex multiplication$${\displaystyle y^2=x^3+ax}$$there the ${\displaystyle \mathbb{Z}/4}$-involution sending ${\displaystyle (t,s)\mapsto (-t,\sqrt{-1}\cdot s)}$. The other special case is when ${\displaystyle a=0}$, so a curve of the form$${\displaystyle y^2=x^3+b}$$ there is the ${\displaystyle \mathbb{Z}/6}$-involution sending ${\displaystyle (t,s)\mapsto ({\zeta }_{3}t,-s)}$ where ${\displaystyle {\zeta }_3}$ is the third root of unity ${\displaystyle e^{2\pi i/3}}$.

There is a subset of the upper-half plane called the Fundamental domain which contains every isomorphism class of elliptic curves. It is the subset$${\displaystyle D=\{z\in 𝔥:|z|\ge 1\text{ and }\text{Re}(z)\le 1/2\}}$$It is useful to consider this space because it helps visualize the stack ${\displaystyle {ℳ}_{1,1}}$. From the quotient map$${\displaystyle 𝔥\to {\text{SL}}_2(\mathbb{Z})\mathrm{\setminus }𝔥}$$the image of ${\displaystyle D}$ is surjective and its interior is injective^{[4]pg 78}. Also, the points on the boundary can be identified with their mirror image under the involution sending ${\displaystyle \text{Re}(z)\mapsto -\text{Re}(z)}$, so ${\displaystyle {ℳ}_{1,1}}$ can be visualized as the projective curve ${\displaystyle {\mathbb{P}}^1}$ with a point removed at infinity^{[5]pg 52}.

There are line bundles ${\displaystyle {ℒ}^{\otimes k}}$ over the moduli stack ${\displaystyle {ℳ}_{1,1}}$ whose sections correspond to modular functions ${\displaystyle f}$ on the upper-half plane ${\displaystyle 𝔥}$. On ${\displaystyle ℂ\times 𝔥}$ there are ${\displaystyle {\text{SL}}_2(\mathbb{Z})}$-actions compatible with the action on ${\displaystyle 𝔥}$ given by$${\displaystyle {\text{SL}}_2(\mathbb{Z})\times {\displaystyle ℂ\times 𝔥}\to {\displaystyle ℂ\times 𝔥}}$$The degree ${\displaystyle k}$ action is given by$${\displaystyle \left(\begin{array}{cc}a& b\\ c& d\end{array}\right):(z,\tau )\mapsto ((c\tau +d{)}^{k}z,\frac{a\tau +b}{c\tau +d})}$$hence the trivial line bundle ${\displaystyle ℂ\times 𝔥\to 𝔥}$ with the degree ${\displaystyle k}$ action descends to a unique line bundle denoted ${\displaystyle {ℒ}^{\otimes k}}$. Notice the action on the factor ${\displaystyle ℂ}$ is a representation of ${\displaystyle {\text{SL}}_2(\mathbb{Z})}$ on ${\displaystyle \mathbb{Z}}$ hence such representations can be tensored together, showing ${\displaystyle {ℒ}^{\otimes k}\otimes {ℒ}^{\otimes l}\cong {ℒ}^{\otimes (k+l)}}$. The sections of ${\displaystyle {ℒ}^{\otimes k}}$ are then functions sections ${\displaystyle f\in \mathrm{\Gamma }(ℂ\times 𝔥)}$ compatible with the action of ${\displaystyle {\text{SL}}_2(\mathbb{Z})}$, or equivalently, functions ${\displaystyle f:𝔥\to ℂ}$ such that$${\displaystyle f(\left(\begin{array}{cc}a& b\\ c& d\end{array}\right)\cdot \tau )=(c\tau +d{)}^{k}f(\tau )}$$ This is exactly the condition for a holomorphic function to be modular.

The modular forms are the modular functions which can be extended to the compactification$${\displaystyle \overline{{ℒ}^{\otimes k}}\to {\overline{ℳ}}_{1,1}}$$this is because in order to compactify the stack ${\displaystyle {ℳ}_{1,1}}$, a point at infinity must be added, which is done through a gluing process by gluing the ${\displaystyle q}$-disk (where a modular function has its ${\displaystyle q}$-expansion)^{[2]pgs 29-33}.

Constructing the universal curves ${\displaystyle ℰ\to {ℳ}_{1,1}}$ is a two step process: (1) construct a versal curve ${\displaystyle {ℰ}_{𝔥}\to 𝔥}$ and then (2) show this behaves well with respect to the ${\displaystyle {\text{SL}}_2(\mathbb{Z})}$-action on ${\displaystyle 𝔥}$. Combining these two actions together yields the quotient stack$${\displaystyle [({\text{SL}}_2(\mathbb{Z})⋉{\mathbb{Z}}^2)\mathrm{\setminus }ℂ\times 𝔥]}$$

Every rank 2 ${\displaystyle \mathbb{Z}}$-lattice in ${\displaystyle ℂ}$ induces a canonical ${\displaystyle {\mathbb{Z}}^2}$-action on ${\displaystyle ℂ}$. As before, since every lattice is homothetic to a lattice of the form ${\displaystyle (1,\tau )}$ then the action ${\displaystyle (m,n)}$ sends a point ${\displaystyle z\in ℂ}$ to$${\displaystyle (m,n)\cdot z\mapsto z+m\cdot 1+n\cdot \tau }$$Because the ${\displaystyle \tau }$ in ${\displaystyle 𝔥}$ can vary in this action, there is an induced ${\displaystyle {\mathbb{Z}}^2}$-action on ${\displaystyle ℂ\times 𝔥}$$${\displaystyle (m,n)\cdot (z,\tau )\mapsto (z+m\cdot 1+n\cdot \tau ,\tau )}$$giving the quotient space$${\displaystyle {ℰ}_{𝔥}\to 𝔥}$$by projecting onto ${\displaystyle 𝔥}$.

There is a ${\displaystyle {\text{SL}}_2(\mathbb{Z})}$-action on ${\displaystyle {\mathbb{Z}}^2}$ which is compatible with the action on ${\displaystyle 𝔥}$, meaning given a point ${\displaystyle z\in 𝔥}$ and a ${\displaystyle g\in {\text{SL}}_2(\mathbb{Z})}$, the new lattice ${\displaystyle g\cdot z}$ and an induced action from ${\displaystyle {\mathbb{Z}}^2\cdot g}$, which behaves as expected. This action is given by$${\displaystyle \left(\begin{array}{cc}a& b\\ c& d\end{array}\right):(m,n)\mapsto (m,n)\cdot \left(\begin{array}{cc}a& b\\ c& d\end{array}\right)}$$which is matrix multiplication on the right, so$${\displaystyle (m,n)\cdot \left(\begin{array}{cc}a& b\\ c& d\end{array}\right)=(am+cn,bm+dn)}$$

• Fundamental domain
• Homothety
• Level structure (algebraic geometry)
• Moduli of abelian varieties
• Shimura variety
• Modular curve
• Elliptic cohomology

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