$\newcommand{\F}{\mathbb F}$
A subset $P$ of the affine plane $\F_p^2$ is said to determine a direction if there is a line in this direction containing at least two points of $P$.

A set of size $|P|>p$ determines all $p+1$ directions, a set of size $|P|\le p$ not contained in a single line determines at least $(|P|+3)/2$ directions; the former is an immediate consequence of the pigeonhole principle, the latter is a highly non-trivial [result of Szonyi][1].

Let's say that a direction in $\F_p^2$ is *rich* if there is a line in this direction containing at least three points of $P$. If $P$ is trapped in a line, or a union of two lines, then there are just one or two rich directions. 

> What is the smallest possible number of rich directions for a set $P\subset\F_p^2$ of size $\frac53\,p<|P|\le 2p$ given that $P$ is not contained in a union of two lines? 

It is easy to construct sets $P$ with about $|P|-p$ rich directions, but it is not clear to me how much better can one do. 

### Added May 04, 2018
The largest possible number of points in general position in $\F_p^2$ is $p+1$, which is quite easy to prove; thus, we are guaranteed to have at least one rich direction. Indeed, I can show that if $\frac32(1+\delta)p\le|P|\le 2p$, then there are at least $\Omega_\delta(\sqrt p)$  rich directions, but I suspect that this can be far from being sharp. 

[1]:https://www.sciencedirect.com/science/article/pii/S0012365X99000977