Homology of Fermat curve












4














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.










share|cite|improve this question



























    4














    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.










    share|cite|improve this question

























      4












      4








      4


      1





      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.










      share|cite|improve this question













      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






      share|cite|improve this question













      share|cite|improve this question











      share|cite|improve this question




      share|cite|improve this question










      asked Nov 21 '18 at 12:58









      57Jimmy

      3,340422




      3,340422






















          0






          active

          oldest

          votes











          Your Answer





          StackExchange.ifUsing("editor", function () {
          return StackExchange.using("mathjaxEditing", function () {
          StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
          StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
          });
          });
          }, "mathjax-editing");

          StackExchange.ready(function() {
          var channelOptions = {
          tags: "".split(" "),
          id: "69"
          };
          initTagRenderer("".split(" "), "".split(" "), channelOptions);

          StackExchange.using("externalEditor", function() {
          // Have to fire editor after snippets, if snippets enabled
          if (StackExchange.settings.snippets.snippetsEnabled) {
          StackExchange.using("snippets", function() {
          createEditor();
          });
          }
          else {
          createEditor();
          }
          });

          function createEditor() {
          StackExchange.prepareEditor({
          heartbeatType: 'answer',
          autoActivateHeartbeat: false,
          convertImagesToLinks: true,
          noModals: true,
          showLowRepImageUploadWarning: true,
          reputationToPostImages: 10,
          bindNavPrevention: true,
          postfix: "",
          imageUploader: {
          brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
          contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
          allowUrls: true
          },
          noCode: true, onDemand: true,
          discardSelector: ".discard-answer"
          ,immediatelyShowMarkdownHelp:true
          });


          }
          });














          draft saved

          draft discarded


















          StackExchange.ready(
          function () {
          StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3007698%2fhomology-of-fermat-curve%23new-answer', 'question_page');
          }
          );

          Post as a guest















          Required, but never shown

























          0






          active

          oldest

          votes








          0






          active

          oldest

          votes









          active

          oldest

          votes






          active

          oldest

          votes
















          draft saved

          draft discarded




















































          Thanks for contributing an answer to Mathematics Stack Exchange!


          • Please be sure to answer the question. Provide details and share your research!

          But avoid



          • Asking for help, clarification, or responding to other answers.

          • Making statements based on opinion; back them up with references or personal experience.


          Use MathJax to format equations. MathJax reference.


          To learn more, see our tips on writing great answers.





          Some of your past answers have not been well-received, and you're in danger of being blocked from answering.


          Please pay close attention to the following guidance:


          • Please be sure to answer the question. Provide details and share your research!

          But avoid



          • Asking for help, clarification, or responding to other answers.

          • Making statements based on opinion; back them up with references or personal experience.


          To learn more, see our tips on writing great answers.




          draft saved


          draft discarded














          StackExchange.ready(
          function () {
          StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3007698%2fhomology-of-fermat-curve%23new-answer', 'question_page');
          }
          );

          Post as a guest















          Required, but never shown





















































          Required, but never shown














          Required, but never shown












          Required, but never shown







          Required, but never shown

































          Required, but never shown














          Required, but never shown












          Required, but never shown







          Required, but never shown







          Popular posts from this blog

          mysqli_query(): Empty query in /home/lucindabrummitt/public_html/blog/wp-includes/wp-db.php on line 1924

          How to change which sound is reproduced for terminal bell?

          Can I use Tabulator js library in my java Spring + Thymeleaf project?