Search: MSC category 11M41
( Other Dirichlet series and zeta functions {For local and global ground fields, see 11R42, 11R52, 11S40, 11S45; for algebrogeometric methods, see 14G10; see also 11E45, 11F66, 11F70, 11F72} )
1. CMB 2015 (vol 59 pp. 119)
2. CMB 2011 (vol 54 pp. 757)
 Sun, Qingfeng

Cancellation of Cusp Forms Coefficients over Beatty Sequences on $\textrm{GL}(m)$
Let $A(n_1,n_2,\dots,n_{m1})$
be the normalized Fourier coefficients of
a Maass cusp form on $\textrm{GL}(m)$.
In this paper, we study the cancellation of $A
(n_1,n_2,\dots,n_{m1})$ over Beatty sequences.
Keywords:Fourier coefficients, Maass cusp form on $\textrm{GL}(m)$, Beatty sequence Categories:11F30, 11M41, 11B83 

3. CMB 2011 (vol 54 pp. 316)
 Mazhouda, Kamel

The SaddlePoint Method and the Li Coefficients
In this paper, we apply the saddlepoint method in conjunction with
the theory of the NÃ¶rlundRice integrals to derive precise
asymptotic formula for the generalized Li coefficients established
by Omar and Mazhouda.
Actually, for any function $F$ in the Selberg class
$\mathcal{S}$ and under the Generalized Riemann Hypothesis, we have
$$
\lambda_{F}(n)=\frac{d_{F}}{2}n\log n+c_{F}n+O(\sqrt{n}\log n),
$$
with
$$
c_{F}=\frac{d_{F}}{2}(\gamma1)+\frac{1}{2}\log(\lambda
Q_{F}^{2}),\ \lambda=\prod_{j=1}^{r}\lambda_{j}^{2\lambda_{j}},
$$
where $\gamma$ is the Euler's constant and the notation is as below.
Keywords:Selberg class, Saddlepoint method, Riemann Hypothesis, Li's criterion Categories:11M41, 11M06 

4. CMB 2007 (vol 50 pp. 11)
 Borwein, David; Borwein, Jonathan

van der Pol Expansions of LSeries
We provide concise series representations for various
Lseries integrals. Different techniques are needed below and above
the abscissa of absolute convergence of the underlying Lseries.
Keywords:Dirichlet series integrals, Hurwitz zeta functions, Plancherel theorems, Lseries Categories:11M35, 11M41, 30B50 

5. CMB 2004 (vol 47 pp. 468)
6. CMB 1997 (vol 40 pp. 364)
 Narayanan, Sridhar

On the nonvanishing of a certain class of Dirichlet series
In this paper,
we consider Dirichlet series with Euler products of the form
$F(s) = \prod_{p}{\bigl(1 + {a_p\over{p^s}}\bigr)}$ in $\Re(s) > 1$,
and which are regular in $\Re(s) \geq 1$ except for a pole of
order $m$ at $s = 1$.
We establish criteria for such a Dirichlet series to be nonvanishing
on the line of convergence. We also show that our results
can be applied to yield nonvanishing results for a subclass of the
Selberg class and the SatoTate conjecture.
Categories:11Mxx, 11M41 
