Properties

 Degree 2 Conductor $2^{2} \cdot 3^{3}$ Sign $0.493 + 0.869i$ Motivic weight 4 Primitive yes Self-dual no Analytic rank 0

Related objects

Dirichlet series

 L(s)  = 1 + (−0.0678 − 3.99i)2-s + (−15.9 + 0.542i)4-s + (−16.6 + 28.7i)5-s + (39.9 − 23.0i)7-s + (3.25 + 63.9i)8-s + (116. + 64.4i)10-s + (63.6 − 36.7i)11-s + (151. − 262. i)13-s + (−95.0 − 158. i)14-s + (255. − 17.3i)16-s + 182.·17-s + 314. i·19-s + (250. − 469. i)20-s + (−151. − 251. i)22-s + (290. + 167. i)23-s + ⋯
 L(s)  = 1 + (−0.0169 − 0.999i)2-s + (−0.999 + 0.0339i)4-s + (−0.664 + 1.15i)5-s + (0.815 − 0.471i)7-s + (0.0508 + 0.998i)8-s + (1.16 + 0.644i)10-s + (0.525 − 0.303i)11-s + (0.896 − 1.55i)13-s + (−0.484 − 0.807i)14-s + (0.997 − 0.0677i)16-s + 0.629·17-s + 0.870i·19-s + (0.625 − 1.17i)20-s + (−0.312 − 0.520i)22-s + (0.549 + 0.317i)23-s + ⋯

Functional equation

\begin{aligned}\Lambda(s)=\mathstrut & 108 ^{s/2} \, \Gamma_{\C}(s) \, L(s)\cr =\mathstrut & (0.493 + 0.869i)\, \overline{\Lambda}(5-s) \end{aligned}
\begin{aligned}\Lambda(s)=\mathstrut & 108 ^{s/2} \, \Gamma_{\C}(s+2) \, L(s)\cr =\mathstrut & (0.493 + 0.869i)\, \overline{\Lambda}(1-s) \end{aligned}

Invariants

 $$d$$ = $$2$$ $$N$$ = $$108$$    =    $$2^{2} \cdot 3^{3}$$ $$\varepsilon$$ = $0.493 + 0.869i$ motivic weight = $$4$$ character : $\chi_{108} (91, \cdot )$ primitive : yes self-dual : no analytic rank = $$0$$ Selberg data = $$(2,\ 108,\ (\ :2),\ 0.493 + 0.869i)$$ $$L(\frac{5}{2})$$ $$\approx$$ $$1.36324 - 0.793433i$$ $$L(\frac12)$$ $$\approx$$ $$1.36324 - 0.793433i$$ $$L(3)$$ not available $$L(1)$$ not available

Euler product

$L(s) = \prod_{p \text{ prime}} F_p(p^{-s})^{-1}$where, for $p \notin \{2,\;3\}$,$$F_p(T)$$ is a polynomial of degree 2. If $p \in \{2,\;3\}$, then $F_p(T)$ is a polynomial of degree at most 1.
$p$$F_p(T)$
bad2 $$1 + (0.0678 + 3.99i)T$$
3 $$1$$
good5 $$1 + (16.6 - 28.7i)T + (-312.5 - 541. i)T^{2}$$
7 $$1 + (-39.9 + 23.0i)T + (1.20e3 - 2.07e3i)T^{2}$$
11 $$1 + (-63.6 + 36.7i)T + (7.32e3 - 1.26e4i)T^{2}$$
13 $$1 + (-151. + 262. i)T + (-1.42e4 - 2.47e4i)T^{2}$$
17 $$1 - 182.T + 8.35e4T^{2}$$
19 $$1 - 314. iT - 1.30e5T^{2}$$
23 $$1 + (-290. - 167. i)T + (1.39e5 + 2.42e5i)T^{2}$$
29 $$1 + (357. + 618. i)T + (-3.53e5 + 6.12e5i)T^{2}$$
31 $$1 + (-985. - 568. i)T + (4.61e5 + 7.99e5i)T^{2}$$
37 $$1 - 1.00e3T + 1.87e6T^{2}$$
41 $$1 + (-557. + 965. i)T + (-1.41e6 - 2.44e6i)T^{2}$$
43 $$1 + (-2.18e3 + 1.25e3i)T + (1.70e6 - 2.96e6i)T^{2}$$
47 $$1 + (980. - 566. i)T + (2.43e6 - 4.22e6i)T^{2}$$
53 $$1 - 1.05e3T + 7.89e6T^{2}$$
59 $$1 + (878. + 507. i)T + (6.05e6 + 1.04e7i)T^{2}$$
61 $$1 + (430. + 745. i)T + (-6.92e6 + 1.19e7i)T^{2}$$
67 $$1 + (-559. - 322. i)T + (1.00e7 + 1.74e7i)T^{2}$$
71 $$1 - 9.56e3iT - 2.54e7T^{2}$$
73 $$1 - 1.89e3T + 2.83e7T^{2}$$
79 $$1 + (6.76e3 - 3.90e3i)T + (1.94e7 - 3.37e7i)T^{2}$$
83 $$1 + (-7.05e3 + 4.07e3i)T + (2.37e7 - 4.11e7i)T^{2}$$
89 $$1 + 7.65e3T + 6.27e7T^{2}$$
97 $$1 + (6.36e3 + 1.10e4i)T + (-4.42e7 + 7.66e7i)T^{2}$$
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\begin{aligned}L(s) = \prod_p \ \prod_{j=1}^{2} (1 - \alpha_{j,p}\, p^{-s})^{-1}\end{aligned}

Imaginary part of the first few zeros on the critical line

−12.62815963764482562489211041133, −11.44921063763272024520946545544, −10.88614834248582740830076984457, −10.04733039719181573096635941046, −8.378350938481854054796116560817, −7.57714222541508393558869602371, −5.74036479620076693075357074052, −4.00257009168146121355745627703, −3.04589786265483846174097865661, −1.02028424773004737401682230486, 1.13409779500929128504192943748, 4.18311904255276478535197630988, 4.94247330685314476725040561906, 6.41596090557727148510567079805, 7.76447617346977358412945666101, 8.746114246434679158721417549033, 9.316685714942198721442394647309, 11.31344453100092066092574309663, 12.21107385185110993551703938952, 13.29884387952047465020500359318