Note on the union-closed sets conjecture

The union-closed sets conjecture states that if a family of sets $\mathcal{A} \neq \{\emptyset\}$ is union-closed, then there is an element which belongs to at least half the sets in $\mathcal{A}$. In 2001, D. Reimer showed that the average set size of a union-closed family, $\mathcal{A}$, is at least $\frac{1}{2} \log_2 |\mathcal{A}|$. In order to do so, he showed that all union-closed families satisfy a particular condition, which in turn implies the preceding bound. Here, answering a question raised in the context of T. Gowers' polymath project on the union-closed sets conjecture, we show that Reimer's condition alone is not enough to imply that there is an element in at least half the sets.


Introduction
Given the set [n] = {1, . . . , n} and a family A ⊆ 2 [n] we say A is union-closed if for A, B ∈ A we have A ∪ B ∈ A. The Union-Closed Sets Conjecture, due to P. Frankl [3], states that if A ⊆ 2 [n] is union-closed and A = {∅} then there is some element of [n] which belongs to at least half the sets in A. One method of approaching this conjecture is to look at the average frequency of an element or, equivalently, the average set size. The following theorem of D. Reimer [2] was thus motivated by and can be shown to follow from, the union-closed sets conjecture.
and is union-closed, then Reimer's proof of Theorem 1 consists of two steps. He first shows that every union-closed family A satisfies Condition 1. He then shows that Condition 1 implies Theorem 1.
In 2016, T. Gowers began a polymath project focused on the union-closed sets conjecture. In the comments on the initial post I. Balla first proposed the conjecture below. Gowers reiterates this conjecture in his second post focused on strengthenings of the union-closed sets conjecture. In the comments there is a discussion of a possible counterexample, and it is stated that all families with ground set at most 5 and a random sampling of families with ground set at most 12 have been confirmed to satisfy the conjecture [1].

Conjecture 1. Assume A ⊆ 2 [n] satisfies Condition 1. Then there is an element x ∈ [n] in at least half the sets of A.
As Reimer showed that all union-closed families satisfy Condition 1, this conjecture is clearly a strengthening of the union-closed sets conjecture. The purpose of this note is to show that Conjecture 1 is false.

Counterexample
In what follows we will always have A and F as in Definition 1.

Note 1. An equivalent way of stating the second part of Condition 1 is that at least one of
We will use the following notation: Before giving the counterexample we will briefly describe how we found it and indicate why no smaller example is possible. The following observation was our starting point. Furthermore, the number of sets containing i is simply the out-degree of i plus 1 (since i ∈ A 0 ). Since D has k vertices and contains a tournament it has maximum out-degree at least k−1 2 . Hence there is always an element in at least k+1 2 members of A. We first observe that if n is the smallest integer such that there is a counterexample to Conjecture 1 on [n] and A is such a counterexample, then F must contain all sets of size n − 1. To see this suppose instead that the elements of F of size n − 1 are [n] \ {i} for i ∈ [k] with k < n. Since F is a filter we have {k + 1, . . . , n} ⊆ F for all F ∈ F , implying that the condition in Note 1 is not affected if we replace each X ∈ A ∪ F by X \ {k + 1, . . . , n}. This produces a counterexample on a smaller set, contradicting the minimality of n.
Restrict A to A ′ := {A i } n i=0 . If n is even then there exists x ∈ [n] with |A ′ x | ≥ n+2 2 . Hence we need at least two sets in A \ A ′ . (If n is odd similar reasoning shows that there must be at least three sets in A \ A ′ .) In our example we will take n to be even and F to consist of [n] \ {1, 2} and [n] \ {3, 4} along with all sets of size at least n − 1. Thus |F | = |A| = n + 3, A 0 = [n], and we want to arrange that |A x | ≤ n 2 + 1 for all x ∈ [n]. We will use the same digraph, D, as in the proof of Fact 1 (with (i, j) an edge if and only if i ∈ A j ). Note that the B i,j 's do not affect the digraph. By Note 1 we know that if B i,j ∈ A then i ∈ A j and j ∈ A i . Therefore, the sum of the out-degrees in D must be at least n 2 −n 2 + 2. Without loss of generality 1 ∈ B 3,4 , since B 1,2 and B 3,4 must satisfy the condition of Note 1. Additionally, if B 1,2 = ∅ then to satisfy Note 1 all other sets in A must contain 1 or 2. However, A 0 contains both 1 and 2, so one of 1 or 2 must appear in at least half the sets, contradicting that A is a counterexample. Hence, B 1,2 and B 3,4 are both nonempty, so we must have at least 2 vertices of out-degree no more than n 2 − 1 and the rest of out-degree no more than n 2 . (If |A \ A ′ | > 2 then we get even more "extra" degrees and the following lower bound on n increases.) Thus we have the inequality 2( n 2 − 1) + (n − 2)( n 2 ) ≥ n 2 −n 2 + 2, i.e. n ≥ 8. When n is odd similar consideration gives n ≥ 13; so, since our example does indeed use n = 8 it is of the smallest possible size.
Counterexample 1. Here we will take our universe to be [8]. Our family A consists of the following 11 sets: • A 1 = {2, 4, 6, 7, 8} • A 2 = {1, 3, 5, 8} We (or our computers) can easily check that the requirement in Note 1 is satisfied and that each element appears in exactly 5 sets.