Let $D$ be an integer number and let $\chi$ be the Dirichlet character defined by $$\chi(m) = 0 \text{ if $m$ even, } \chi(m) = (D/m) \text{ if $m$ odd,}$$ where $(D/m)$ denotes the Jacobi symbol. Let us denote by $\zeta_D(s)$ its L-series: $$ \zeta_D(s) = L(s,\chi) = \sum_{n = 1}^\infty \frac{\chi(n)}{n^s} = \prod_p \frac{1}{1-(D/p)p^{-s}},$$ where $(D/p) = 0$ if $p | 2d$.
For $s > 1$ there are the following bounds: $$\frac{\zeta(2s)}{\zeta(s)} = \prod_p \frac{1}{1+p^{-s}} \leq \zeta_D(s) \leq \prod_p \frac{1}{1-p^{-s}} = \zeta(s).$$ Both of them become trivial for $s = 1$. Still, $\zeta_D(1)$ is a finite positive number for $D < 0$.
Consider the sequence $$ \zeta_{-d}(1),\, d = 1,2,3,\ldots$$ Is this sequence bounded above or below? If yes, what is an upper or lower bound?
