The zeta function for the semiprimes is
\begin{aligned}
& \zeta_{\Omega_ 2} (s) = \exp \sum _k^\infty \frac{P (k s)^2+P(2 k s)}{2 k}
\end{aligned}
where $P$ is the prime zeta function. But the zeros are hard to find. I calculated the near-zeros along the line $1/2 +it$ with
func[t_] := 1/Abs[Exp[(PrimeZetaP[(1/2 + I t)]^2 + PrimeZetaP[2 (1/2 + I t)])/2]];
data = Table[{t, func[t]}, {t, .01, #, .01}] &[(**)10^4];
peaks = Pick[data, PeakDetect[data[[;; , 2]], .01, .001], 1];
in Mathematica, which takes a long time to evaluate, so I uploaded the data here:
peaks = ToExpression[Import["https://raw.githubusercontent.com/martinq321/peaks/main/omega2"]];
Below is a plot of the absolute value of the first term of $\zeta_{\Omega_ 2} (s)$
$\left| \exp \left(P \left (1/2+ i t \right)^2/2+P \left(1+ 2i t \right)/2\right)\right|$ with the red lines marking near-zero points:
[![enter image description here][1]][1]
Given the above, the plot below shows
\begin{aligned}
&\sum _{k \in \text{peaks}} -\frac{\cos (k \log t)}{\ \sqrt{k}}, \quad 200 \geq t \geq 250
\end{aligned}
where, despite the noise, the peaks show at the semiprimes and the primes:
[![enter image description here][2]][2]
and shows even clearer with the noise cleared up a bit:
[![enter image description here][3]][3]
li2 = Select[peaks, #[[2]] > 5 &][[All, 1]]; x1 = 200; x2 = 250;
data1 = Table[(Sum[-Cos[li2[[p]] Log[t]]/Sqrt@p,
{p, Length@li2}]), {t, x1, x2, .1}];
ListLinePlot[BilateralFilter[data1, 1., 1, MaxIterations -> 25],
PlotStyle -> {AbsoluteThickness[3]}, DataRange -> {x1, x2},
ImageSize -> 700, Frame -> True, AspectRatio -> 1/8]
What is going on here? I presume the peaks are also peaking at the primes because many of the 'zeros' are very close to the zeros of the zeta function. Is there a way to filter them out? Is there a better way to find the zeros of $\zeta_{\Omega_ 2} (s)$?
[1]: https://i.sstatic.net/vh8pF.png
[2]: https://i.sstatic.net/vP6Wz.png
[3]: https://i.sstatic.net/uW236.png