Dirichlet series
| $L(s, E, \mathrm{sym}^{2})$ = 1 | + 0.333·3-s + 0.200·5-s − 7-s + 0.111·9-s + 0.454·11-s + 1.76·13-s + 0.0666·15-s + 1.11·17-s − 0.157·19-s − 0.333·21-s − 23-s + 0.0400·25-s + 0.0370·27-s − 0.862·29-s + 1.06·31-s + 0.151·33-s − 0.200·35-s − 0.891·37-s + 0.589·39-s − 0.121·41-s + 2.34·43-s + 0.0222·45-s + 0.361·47-s + 2·49-s + 0.372·51-s − 0.320·53-s + 0.0909·55-s + ⋯ |
Functional equation
\[\begin{aligned}\Lambda(s,E,\mathrm{sym}^{2})=\mathstrut & 3600 ^{s/2} \, \Gamma_{\R}(s+1) \, \Gamma_{\C}(s+1) \, L(s, E, \mathrm{sym}^{2})\cr =\mathstrut & \, \Lambda(1-{s}, E,\mathrm{sym}^{2}) \end{aligned}\]
Invariants
| Degree: | \(3\) |
| Conductor: | \(3600\) = \(2^{4} \cdot 3^{2} \cdot 5^{2}\) |
| Sign: | $1$ |
| Arithmetic: | yes |
| Primitive: | yes |
| Self-dual: | yes |
| Selberg data: | \((3,\ 3600,\ (1:1.0),\ 1)\) |
Particular Values
\[L(1/2, E, \mathrm{sym}^{2}) \approx 1.940920006\]
\[L(1, E, \mathrm{sym}^{2}) \approx 1.283089288\]
Euler product
\(L(s, E, \mathrm{sym}^{2}) = (1-3^{- s})^{-1}(1-5^{- s})^{-1}\prod_{p \nmid 120 }\prod_{j=0}^{2} \left(1- \frac{\alpha_p^j\beta_p^{2-j}}{p^{s}} \right)^{-1}\)
Imaginary part of the first few zeros on the critical line