A generalisation of Sperner families (union-free families)

Question

I am interested in a family of sets $C$ with the following property:

• if you take any $k$ distinct subsets $S_1, S_2, \dotsc, S_k \in C$, then $S_1$ is not a subset of $S_2 \cup S_3 \cup \dotso \cup S_k$.

If we have $k = 2$, these are Sperner families.

Has the case $k > 2$ been discussed in the literature?

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Edit: A colleague just pointed out that Jukna (2011): "Extremal Combinatorics", Section 8.6 briefly discusses these families and gives some references. The book uses the term union-free families.

However, it seems that none of the results mentioned in the book address the following corner case that I am mainly interested in:

• The size of the universe $U$ is $O(k)$.
• The size of the family is "non-trivial" (say, $\Omega(k^2)$).

I would like to know more about positive results for this case (I do not need an explicit construction; an existential result is fine).

It seems that in the literature, the main focus has been on families that are exponentially large in $|U|$, and to construct such families we need to have a fairly large $|U|$ in comparison with $k$. However, I would like to understand the case of a small $|U|$ (and not necessarily exponentially large $|C|$).

Answer 1

For $k=3$ case, there is a result of Kleitman, Shearer and Sturtevant, which gives a bound of $2^{0.7549 n}$ on the size of $C$. In fact they show a similar bound for a $k$-uniform family for any $k$. In a follow-up paper by Alon an explicit set family of exponential size is constructed.