Timeline for Hecke operators on universal elliptic curves
Current License: CC BY-SA 4.0
13 events
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| Oct 3, 2022 at 2:29 | history | edited | Adithya Chakravarthy | CC BY-SA 4.0 |
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| Oct 2, 2022 at 2:45 | comment | added | GH from MO | Please use a high-level tag like "nt.number-theory". I added this tag now. | |
| Oct 2, 2022 at 2:45 | history | edited | GH from MO |
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| Oct 1, 2022 at 23:25 | history | became hot network question | |||
| Oct 1, 2022 at 23:14 | vote | accept | Adithya Chakravarthy | ||
| Oct 1, 2022 at 23:13 | vote | accept | Adithya Chakravarthy | ||
| Oct 1, 2022 at 23:14 | |||||
| Oct 1, 2022 at 23:06 | answer | added | Will Sawin | timeline score: 4 | |
| Oct 1, 2022 at 21:50 | comment | added | Adithya Chakravarthy | @WillSawin A follow up on this: in what sense is $H^0(E, \Omega_{E/Y_1(N)})$ isomorphic to $M_1(Y_1(N))$? The former space is differential forms on $E$, whereas the latter space is differential forms on $Y_1(N)$. How do you get a differential form on $E$ and produce from it a differential form on $Y_1(N)$? | |
| Oct 1, 2022 at 17:32 | history | edited | Adithya Chakravarthy | CC BY-SA 4.0 |
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| Oct 1, 2022 at 17:22 | history | edited | Adithya Chakravarthy | CC BY-SA 4.0 |
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| Oct 1, 2022 at 17:21 | comment | added | Adithya Chakravarthy | edited the question, thanks for the correction. | |
| Oct 1, 2022 at 15:44 | comment | added | Will Sawin | I think the eigenvalues will rather come from modular forms of weight $1$, since $H^0(E, \Omega_{E/Y_1(N)}$ is the space of modular forms of weight $1$ and level $N$. | |
| Oct 1, 2022 at 15:21 | history | asked | Adithya Chakravarthy | CC BY-SA 4.0 |