Homology of Fermat curve
Let $C(n):X^n+Y^n=Z^n$ be the plane projective Fermat curve of degree $n$ over $mathbb{C}$.
Shorter version of the question: How can I describe explicit representatives for a basis for the singular homology $H_1(C(n),mathbb{Q})$?
Longer version of the question: Consider the following paths on $C(n)$:
$$ gamma_{r,s} : [0,1]to C(n), quad t mapsto [zeta^r(1-t)^{1/n}:zeta^st^{1/n}:1],$$
where $zeta$ is a primitive $n-$th root of unity and $r,s in mathbb{Z}/nmathbb{Z}$. One can combine them to obtain cycles
$$ Delta_{r,s} := [gamma_{0,s}-gamma_{r,s}+gamma_{r,0}-gamma_{-r,0} + gamma_{-r,-s}-gamma_{0,-s}] in H_1(C(n),mathbb{Q})^-$$
that are anti-invariant under complex conjugation (that's what the $^-$ stands for), meaning that $overline{Delta_{r,s}}=-Delta_{r,s}$. My aim is to show that the $Delta_{r,s}$ span $H_1(C(n),mathbb{Q})^-$, which has dimension equal to the genus
$$g=dfrac{(n-1)(n-2)}{2}.$$
There are in principle enough elements. It's true that $Delta_{r,0}=Delta_{0,s}=0$ and that $Delta_{-r,-s}=-Delta_{r,s}$ and that $Delta_{frac{n}{2},frac{n}{2}}=0$ for $n$ even, but one could in principle still find up to
$$leftlfloor frac{(n-1)^2}{2} rightrfloor ge g$$
cycles among the $Delta_{r,s}$, and based on computer calculations I have reason to believe that they actually span $H_1(C(n),mathbb{Q})^-$. But I would like to prove it. So I either need a direct argument or, if I can find a basis of $H_1(C(n),mathbb{Q})$, I could try to express the $Delta_{r,s}$ in terms of this basis and see what comes out.
The problem is that I do not have a nice way to visualize paths on the curve and describe them with explicit formulas.
Ideas:
- Of course one can take the standard basis on the compact Riemann surface with $g$ holes, but then to go from there to the concrete case of $C(n)$ probably requires complicated formulas (I honestly would have no idea how to do it).
- Find a basis of $H_1(C(n),mathbb{Q})$ by induction. The cases with $n=1,2$ have trivial homology, so we just need the step. But it's difficult to do it without an idea for an explicit formula.
- Look at the Jacobian $J(n)$. It has the same homology as $C(n)$. It can be contructed as
$$ J(n) = frac{left(Omega^{1}_{C(n)}right)^*}{Lambda},$$
i.e., as the dual of global holomorphic differential $1-$forms on $C(n)$ quotiented by the span $Lambda$ of the functionals on $Omega^{1}_{C(n)}$ of the form $lambda = int_{[c]} cdot$ for some $[c] in H_1(C(n),mathbb{Q})$. $Omega^{1}_{C(n)}$ is a complex vector space of dimension $g$, so if one finds a basis one can view $J(n)$ as $mathbb{C}^g$ quotient a lattice, and cycles might be easier to describe there. And maybe, if one finds a basis of the homology of $J(n)$, its pullback via the Abel-Jacobi map $C(n) to J(n)$ to $C(n)$ is again a basis and one can do something. But I am not sure about many points here.
algebraic-geometry homology-cohomology algebraic-curves riemann-surfaces
add a comment |
Let $C(n):X^n+Y^n=Z^n$ be the plane projective Fermat curve of degree $n$ over $mathbb{C}$.
Shorter version of the question: How can I describe explicit representatives for a basis for the singular homology $H_1(C(n),mathbb{Q})$?
Longer version of the question: Consider the following paths on $C(n)$:
$$ gamma_{r,s} : [0,1]to C(n), quad t mapsto [zeta^r(1-t)^{1/n}:zeta^st^{1/n}:1],$$
where $zeta$ is a primitive $n-$th root of unity and $r,s in mathbb{Z}/nmathbb{Z}$. One can combine them to obtain cycles
$$ Delta_{r,s} := [gamma_{0,s}-gamma_{r,s}+gamma_{r,0}-gamma_{-r,0} + gamma_{-r,-s}-gamma_{0,-s}] in H_1(C(n),mathbb{Q})^-$$
that are anti-invariant under complex conjugation (that's what the $^-$ stands for), meaning that $overline{Delta_{r,s}}=-Delta_{r,s}$. My aim is to show that the $Delta_{r,s}$ span $H_1(C(n),mathbb{Q})^-$, which has dimension equal to the genus
$$g=dfrac{(n-1)(n-2)}{2}.$$
There are in principle enough elements. It's true that $Delta_{r,0}=Delta_{0,s}=0$ and that $Delta_{-r,-s}=-Delta_{r,s}$ and that $Delta_{frac{n}{2},frac{n}{2}}=0$ for $n$ even, but one could in principle still find up to
$$leftlfloor frac{(n-1)^2}{2} rightrfloor ge g$$
cycles among the $Delta_{r,s}$, and based on computer calculations I have reason to believe that they actually span $H_1(C(n),mathbb{Q})^-$. But I would like to prove it. So I either need a direct argument or, if I can find a basis of $H_1(C(n),mathbb{Q})$, I could try to express the $Delta_{r,s}$ in terms of this basis and see what comes out.
The problem is that I do not have a nice way to visualize paths on the curve and describe them with explicit formulas.
Ideas:
- Of course one can take the standard basis on the compact Riemann surface with $g$ holes, but then to go from there to the concrete case of $C(n)$ probably requires complicated formulas (I honestly would have no idea how to do it).
- Find a basis of $H_1(C(n),mathbb{Q})$ by induction. The cases with $n=1,2$ have trivial homology, so we just need the step. But it's difficult to do it without an idea for an explicit formula.
- Look at the Jacobian $J(n)$. It has the same homology as $C(n)$. It can be contructed as
$$ J(n) = frac{left(Omega^{1}_{C(n)}right)^*}{Lambda},$$
i.e., as the dual of global holomorphic differential $1-$forms on $C(n)$ quotiented by the span $Lambda$ of the functionals on $Omega^{1}_{C(n)}$ of the form $lambda = int_{[c]} cdot$ for some $[c] in H_1(C(n),mathbb{Q})$. $Omega^{1}_{C(n)}$ is a complex vector space of dimension $g$, so if one finds a basis one can view $J(n)$ as $mathbb{C}^g$ quotient a lattice, and cycles might be easier to describe there. And maybe, if one finds a basis of the homology of $J(n)$, its pullback via the Abel-Jacobi map $C(n) to J(n)$ to $C(n)$ is again a basis and one can do something. But I am not sure about many points here.
algebraic-geometry homology-cohomology algebraic-curves riemann-surfaces
add a comment |
Let $C(n):X^n+Y^n=Z^n$ be the plane projective Fermat curve of degree $n$ over $mathbb{C}$.
Shorter version of the question: How can I describe explicit representatives for a basis for the singular homology $H_1(C(n),mathbb{Q})$?
Longer version of the question: Consider the following paths on $C(n)$:
$$ gamma_{r,s} : [0,1]to C(n), quad t mapsto [zeta^r(1-t)^{1/n}:zeta^st^{1/n}:1],$$
where $zeta$ is a primitive $n-$th root of unity and $r,s in mathbb{Z}/nmathbb{Z}$. One can combine them to obtain cycles
$$ Delta_{r,s} := [gamma_{0,s}-gamma_{r,s}+gamma_{r,0}-gamma_{-r,0} + gamma_{-r,-s}-gamma_{0,-s}] in H_1(C(n),mathbb{Q})^-$$
that are anti-invariant under complex conjugation (that's what the $^-$ stands for), meaning that $overline{Delta_{r,s}}=-Delta_{r,s}$. My aim is to show that the $Delta_{r,s}$ span $H_1(C(n),mathbb{Q})^-$, which has dimension equal to the genus
$$g=dfrac{(n-1)(n-2)}{2}.$$
There are in principle enough elements. It's true that $Delta_{r,0}=Delta_{0,s}=0$ and that $Delta_{-r,-s}=-Delta_{r,s}$ and that $Delta_{frac{n}{2},frac{n}{2}}=0$ for $n$ even, but one could in principle still find up to
$$leftlfloor frac{(n-1)^2}{2} rightrfloor ge g$$
cycles among the $Delta_{r,s}$, and based on computer calculations I have reason to believe that they actually span $H_1(C(n),mathbb{Q})^-$. But I would like to prove it. So I either need a direct argument or, if I can find a basis of $H_1(C(n),mathbb{Q})$, I could try to express the $Delta_{r,s}$ in terms of this basis and see what comes out.
The problem is that I do not have a nice way to visualize paths on the curve and describe them with explicit formulas.
Ideas:
- Of course one can take the standard basis on the compact Riemann surface with $g$ holes, but then to go from there to the concrete case of $C(n)$ probably requires complicated formulas (I honestly would have no idea how to do it).
- Find a basis of $H_1(C(n),mathbb{Q})$ by induction. The cases with $n=1,2$ have trivial homology, so we just need the step. But it's difficult to do it without an idea for an explicit formula.
- Look at the Jacobian $J(n)$. It has the same homology as $C(n)$. It can be contructed as
$$ J(n) = frac{left(Omega^{1}_{C(n)}right)^*}{Lambda},$$
i.e., as the dual of global holomorphic differential $1-$forms on $C(n)$ quotiented by the span $Lambda$ of the functionals on $Omega^{1}_{C(n)}$ of the form $lambda = int_{[c]} cdot$ for some $[c] in H_1(C(n),mathbb{Q})$. $Omega^{1}_{C(n)}$ is a complex vector space of dimension $g$, so if one finds a basis one can view $J(n)$ as $mathbb{C}^g$ quotient a lattice, and cycles might be easier to describe there. And maybe, if one finds a basis of the homology of $J(n)$, its pullback via the Abel-Jacobi map $C(n) to J(n)$ to $C(n)$ is again a basis and one can do something. But I am not sure about many points here.
algebraic-geometry homology-cohomology algebraic-curves riemann-surfaces
Let $C(n):X^n+Y^n=Z^n$ be the plane projective Fermat curve of degree $n$ over $mathbb{C}$.
Shorter version of the question: How can I describe explicit representatives for a basis for the singular homology $H_1(C(n),mathbb{Q})$?
Longer version of the question: Consider the following paths on $C(n)$:
$$ gamma_{r,s} : [0,1]to C(n), quad t mapsto [zeta^r(1-t)^{1/n}:zeta^st^{1/n}:1],$$
where $zeta$ is a primitive $n-$th root of unity and $r,s in mathbb{Z}/nmathbb{Z}$. One can combine them to obtain cycles
$$ Delta_{r,s} := [gamma_{0,s}-gamma_{r,s}+gamma_{r,0}-gamma_{-r,0} + gamma_{-r,-s}-gamma_{0,-s}] in H_1(C(n),mathbb{Q})^-$$
that are anti-invariant under complex conjugation (that's what the $^-$ stands for), meaning that $overline{Delta_{r,s}}=-Delta_{r,s}$. My aim is to show that the $Delta_{r,s}$ span $H_1(C(n),mathbb{Q})^-$, which has dimension equal to the genus
$$g=dfrac{(n-1)(n-2)}{2}.$$
There are in principle enough elements. It's true that $Delta_{r,0}=Delta_{0,s}=0$ and that $Delta_{-r,-s}=-Delta_{r,s}$ and that $Delta_{frac{n}{2},frac{n}{2}}=0$ for $n$ even, but one could in principle still find up to
$$leftlfloor frac{(n-1)^2}{2} rightrfloor ge g$$
cycles among the $Delta_{r,s}$, and based on computer calculations I have reason to believe that they actually span $H_1(C(n),mathbb{Q})^-$. But I would like to prove it. So I either need a direct argument or, if I can find a basis of $H_1(C(n),mathbb{Q})$, I could try to express the $Delta_{r,s}$ in terms of this basis and see what comes out.
The problem is that I do not have a nice way to visualize paths on the curve and describe them with explicit formulas.
Ideas:
- Of course one can take the standard basis on the compact Riemann surface with $g$ holes, but then to go from there to the concrete case of $C(n)$ probably requires complicated formulas (I honestly would have no idea how to do it).
- Find a basis of $H_1(C(n),mathbb{Q})$ by induction. The cases with $n=1,2$ have trivial homology, so we just need the step. But it's difficult to do it without an idea for an explicit formula.
- Look at the Jacobian $J(n)$. It has the same homology as $C(n)$. It can be contructed as
$$ J(n) = frac{left(Omega^{1}_{C(n)}right)^*}{Lambda},$$
i.e., as the dual of global holomorphic differential $1-$forms on $C(n)$ quotiented by the span $Lambda$ of the functionals on $Omega^{1}_{C(n)}$ of the form $lambda = int_{[c]} cdot$ for some $[c] in H_1(C(n),mathbb{Q})$. $Omega^{1}_{C(n)}$ is a complex vector space of dimension $g$, so if one finds a basis one can view $J(n)$ as $mathbb{C}^g$ quotient a lattice, and cycles might be easier to describe there. And maybe, if one finds a basis of the homology of $J(n)$, its pullback via the Abel-Jacobi map $C(n) to J(n)$ to $C(n)$ is again a basis and one can do something. But I am not sure about many points here.
algebraic-geometry homology-cohomology algebraic-curves riemann-surfaces
algebraic-geometry homology-cohomology algebraic-curves riemann-surfaces
asked Nov 21 '18 at 12:58
57Jimmy
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3,340422
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