Let $\Lambda=\left\{ \lambda_{n}\right\} _{n=0}^{\infty}$ be an infinite, strictly increasing sequence of non-negative integers. I say that $\Lambda$ is reciprocal-summable if: $$\sum_{\lambda\in\Lambda\backslash\left\{ 0\right\} }\frac{1}{\lambda}<\infty$$
Now, in a slight abuse of terminology, I'm going to use the term “lacunary” to refer only to those holomorphic functions on $\mathbb{D}$ for which the unit circle is a natural boundary (such as $\sum_{n=0}^{\infty}z^{2^{n}}$). The only functions I'm concerned with are those for which the power series coefficients are $0$s and $1$s.
I've been reading up on the known criteria (and converses) for when a function is lacunary (results of Fabry, Hadamard, Pólya, etc.). However, many (if not most) of them try to go from the most general point of view they can find, and so, I can't seem to find the exact details / answers that I'm looking for.
The claims which I would like to have answered (either partially or entirely) and/or be pointed toward a counterexample of are as follows:
I. If $\Lambda$ is reciprocal summable, then $\sum_{n=0}^{\infty}z^{\lambda_{n}}$ is lacunary.
II. If $\Lambda$ is not reciprocal-summable, then $\sum_{n=0}^{\infty}z^{\lambda_{n}}$ is not lacunary.
If any of the results (or predecessors thereof) of Hadamard, Fabry, Pólya (etc.) imply one or more of these claims, an explanation of how they do so would be much appreciated.
Thanks in advance!