Are there examples of Mellin transforms of functions $ \int_{0}^{\infty}f(x)x^{s-1}\mathrm dx$ that have only real zeroes or have only zeroes on the critical line?
For example, the Mellin transform of the Hermite polynomials has zeroes on the critical line $\mathrm{Re}(s)=1/2$. Can this fact be extended to the Mellin transform of any function $ f(x)$ which is its own Fourier transform ? $ F(f(x))=kf(x) $
The 'modified' Bessel function, or MacDonald's function, is more or less a Mellin transform of the order $s$: $$ K_s(x)=\frac12(\frac x2)^s\int_0^\infty\exp(-t-(x^2/4t))t^{-s}\frac{dt}{t} $$ once you swap $s$ for $-s$ and move the leading term to the other side. And $K_s(x)=K_{-s}(x)$, so $K_{it}(x)$ is real for real $x$. I believe all the zeros of $K_s$, as a function of $s$, are on the imaginary axis, but I can't find the reference. Polya did some work with this in connection to the Riemann Hypothesis.