Poisson equation on the complex plane with mixed boundary conditions

I do not have a copy of Blumenhagen, so I am making some assumptions about what you want to do. However, I think I can answer at least some of your questions.

The square roots occur because you need to use a conformal mapping from $z$ to $u = sqrt{z}$ in order to use the image charge method. You can see that you need to have square roots by separating variables in Laplace's equation. The separated solutions are $z^{pmalpha}$ that is $r^{pmalpha}$ multiplying $cos(alphaphi)$ and/or $sin(alphaphi)$. To match your boundary conditions that the $phi$ derivative is zero at $phi=0$ and the function is zero at $phi=pi$, you need the cosine solution with $alpha = (2n+1)/2$ with $n$ integer. This is the real part of $z^{pm (2n+1)/2}$, so you would expect an expansion in the square root of $z$.

To use the image charge method, you can realize that if you want the solution in the upper half plane for the source at position $w$, then $u=sqrt{z}$ with the branch cut chosen on the negative real axis so that with $z=re^{iphi}$, $u=sqrt{r}e^{iphi/2}$, and $-pi < phi < pi$, will map the upper half plane to the upper right quadrant. You can now use the image charge method. You have the mapped source at $sqrt{w}$, so the particular solution is ${rm Re}~ qln(u-sqrt{w})$, the three image charges will be $q$ at $sqrt{bar w}$, and $-q$ at both $-sqrt{w}$, and $-sqrt{bar w}$. Change $u$ to $sqrt{z}$ and fix the magnitude of $q$ to match your source to give your desired solution.