2.1 The definition of $\mathcal{A}\square \mathcal{B}$ for arbitrary events

Let us recall how to extend the definition of $\mathcal{A}\square \mathcal{B}$ to arbitrary events. A subset $C$ of $V$ is in $\mathcal{A}\square \mathcal{B}$ if and only if there are disjoint subsets $V_A$ and $V_B$ of $V$ such that

\begin{equation*}\{D\subseteq V| D\cap V_A=C\cap V_A \}\subseteq \mathcal {A}\end{equation*}

and

\begin{equation*}\{D\subseteq V| D\cap V_B=C\cap V_B \}\subseteq \mathcal {B}.\end{equation*}

If $\mathcal{A}$ and $\mathcal{B}$ are increasing, then this definition indeed coincides with our earlier definition.

2.2 The proof of Theorem 1.4

In this subsection, we prove Theorem 1.4. Note that Theorem 1.1 and Theorem 1.3 can be obtained as special cases of Theorem 1.4.

Our proof will use several ideas of Berg and Jonasson [Reference van den Berg and Jonasson4].

Let $I$ be the set of tuples $(W,K,L,R)$ , where $W$ is a subset of $V$ , $K$ and $L$ are perfect matchings in the induced subgraph $G[W]$ , $R$ is a subgraph of $G[V\backslash W]$ consisting of vertex disjoint paths.Footnote ¹

Fix a linear ordering of the edges of $G$ . Consider an $i=(W,K,L,R)\in I$ . Then $R$ is the vertex disjoint union of the paths $P_1,P_2,\ldots,P_k$ , where we list the paths in increasing order of their lowest edge. We can write $P_j$ as the union of the matchings $M_{j,0}$ and $M_{j,1}$ . This decomposition is unique once we assume that $M_{j,0}$ contains the lowest edge of $P_j$ . For $\omega =(\omega _1,\omega _2,\ldots,\omega _k)\in \{0,1\}^k$ , we define the matchings

\begin{equation*}C_{i,\omega }=K\cup \cup _{j=1}^k M_{j,\omega _j}\quad \text {and}\quad D_{i,\omega }=L\cup \cup _{j=1}^k M_{j,1-\omega _j}.\end{equation*}

Moreover, we define

\begin{equation*}Y_i^C=\left\{C_{i,\omega }|\quad \omega \in \{0,1\}^k\right\},\end{equation*}

\begin{equation*}Y_i^D=\left\{D_{i,\omega }|\quad \omega \in \{0,1\}^k\right\},\end{equation*}

and

\begin{equation*}X_i=\left\{(C_{i,\omega },D_{i,\omega })|\quad \omega \in \{0,1\}^k\right\}.\end{equation*}

Let $H_i$ be the set of endpoints of the paths $P_1,P_2,\ldots,P_k$ . Let $V(R)$ be the vertex set of $R$ . Let $B_i=((W\cup V(R))\Delta S)\backslash H_i$ . Let $v_{j,0}$ and $v_{j,1}$ be the two endpoints of $P_j$ . If we choose the indices in the right way, then we get that

\begin{equation*}B(C_{i,\omega })=B_i\cup \big\{v_{j,\omega _j}\big|\quad j=1,2,\ldots,k\big\},\end{equation*}

and

\begin{equation*}B(D_{i,\omega })=B_i\cup \big\{v_{j,1-\omega _j}\big|\quad j=1,2,\ldots,k\big\}.\end{equation*}

This immediately implies that

(1) \begin{align} \big\{B(C_{i,\omega })\big|\quad \omega \in \big\{0,1\}^k\big\} & =\big\{B\big(D_{i,\omega }\big)\big|\quad \omega \in \{0,1\}^k\big\}\nonumber \\[3pt]& = \big\{B_i\cup H|\quad H\subseteq H_i\text{ and } \big|H\cap \big\{v_{j,0},v_{j,1}\big\}\big|=1\text{ for all }j=1,2,\ldots,k\big\}. \end{align}

Let $U_i=\{v_{j,1}|\quad j=1,2,\ldots,k\}$ . We define the map $\tau _i\,:\,\mathcal{M}\to 2^{U_i}$ by $\tau _i(M)=B(M)\cap U_i$ . It is clear from what is written above that the appropriate restriction of $\tau _i$ gives a bijection from $Y_i^C$ to $2^{U_i}$ , and also from $Y_i^D$ to $2^{U_i}$ . Moreover,

(2) \begin{equation} X_i=\big\{(C,D)\in Y_i^C\times Y_i^D\big|\quad \tau _i(C)=U_i\backslash \tau _i(D)\big\}. \end{equation}

We define

\begin{equation*}\mathcal {M}^{\prime}=\{M\in \mathcal {M}|\quad V_+\subseteq B(M), V_-\cap B(M)=\emptyset \},\end{equation*}

and

\begin{equation*}I^{\prime}=\big\{i\in I|\quad V_+\subseteq B_i, V_-\cap (B_i\cup H_i)=\emptyset \big\}.\end{equation*}

Figure 1. The first figure describes a tuple $i=(W,K,L,R)\in I$ : the vertices of $W$ are coloured black; the bold edges correspond to the edges of $K\cup L\cup R$ ; the labels show the edges of the matchings $K,L$ and the decomposition of $R$ into two paths $P_1$ and $P_2$ , and the two colour classes $S$ and $T$ of the bipartite graphs $G$ . Note that the left most edge belongs to both $K$ and $L$ . In the second figure vertices of $H_i$ are coloured black; the edges of $R=P_1\cup P_2$ are bold; the labels show the indexing of the vertices of $H_i$ , and also the decomposition of the paths $P_1$ and $P_2$ into the matchings $M_{1,0},M_{1,1}$ and $M_{2,0},M_{2,1}$ . The vertical edges are in $M_{1,0}$ and $M_{2,0}$ , the tilted edges are in $M_{1,1}$ and $M_{2,1}$ . (Of course, depending on the linear ordering of the edges, the labels of $M_{1,0}$ and $M_{1,1}$ can be switched, we omitted the linear ordering from these figures.) We used a grey frame to indicate the elements of $U_i$ . In the last four rows, the bold edges correspond to the matchings $C_{i,\omega }$ and $D_{i,\omega }$ as indicated. The vertices in $B(C_{i,\omega })$ (and $B(D_{i,\omega })$ ) are coloured black. The grey frame again contains the vertices of $U_i$ .

Given a subset $\mathcal{F}$ of $2^{V^{\prime}}$ , we define $\mathcal{M}_{\mathcal{F}}$ as $\{M\in \mathcal{M}^{\prime}| B^{\prime}(M)\in \mathcal{F}\}$ .

Let $\mathcal{A}$ and $\mathcal{B}$ be upward closed subsets of $2^{V^{\prime}}$ .

Lemma 2.2. If for all $i\in I^{\prime}$ , we have

(3) \begin{equation} \big|\big(\mathcal{M}_{\mathcal{A}\square \mathcal{B}}\times \mathcal{M}^{\prime}\big)\cap X_i\big|\le \big|\big(\mathcal{M}_{\mathcal{A}}\times \mathcal{M}_{\mathcal{B}}\big)\cap X_i\big|, \end{equation}

then

\begin{equation*}\mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {A}\square \mathcal {B} )\le \mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {A})\mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {B}).\end{equation*}

Proof. Consider any $i\in I^{\prime}$ . If $(C_1,D_1),(C_2,D_2)\in X_i$ , then $C_1+ D_1=C_2+ D_2$ as multisets. In particular, $w(C_1)w(D_1)=w(C_2)w(D_2)$ . Thus, there is a $w_i$ such that $w(C)w(D)=w_i$ for any $(C,D)\in X_i$ . Multiplying both sides of Inequality (3) by $w_i$ , we obtain that

\begin{equation*}\big|\big(\mathcal {M}_{\mathcal {A}\square \mathcal {B}}\times \mathcal {M}^{\prime}\big)\cap X_i\big|\cdot w_i\le \big|\big(\mathcal {M}_{\mathcal {A}}\times \mathcal {M}_{\mathcal {B}}\big)\cap X_i\big|\cdot w_i,\end{equation*}

which is equivalent to

\begin{equation*}\sum _{(C,D)\in \big(\mathcal {M}_{\mathcal {A}\square \mathcal {B}}\times \mathcal {M}^{\prime}\big)\cap X_i}w(C)w(D)\le \sum _{(C,D)\in (\mathcal {M}_{\mathcal {A}}\times \mathcal {M}_{\mathcal {B}})\cap X_i}w(C)w(D).\end{equation*}

Summing these inequalities for all $i\in I^{\prime}$ and using Lemma 2.1, we obtain that

\begin{equation*}\sum _{(C,D)\in \mathcal {M}_{\mathcal {A}\square \mathcal {B}}\times \mathcal {M}^{\prime}}w(C)w(D)\le \sum _{(C,D)\in (\mathcal {M}_{\mathcal {A}}\times \mathcal {M}_{\mathcal {B}})}w(C)w(D).\end{equation*}

This can be rewritten as

\begin{equation*}\left (\sum _{M\in \mathcal {M}_{\mathcal {A}\square \mathcal {B}}}w(M)\right )\left (\sum _{M\in \mathcal {M}^{\prime}} w(M)\right )\le \left (\sum _{M\in \mathcal {M}_{\mathcal {A}}} w(M)\right )\left (\sum _{M\in \mathcal {M}_{\mathcal {B}}} w(M)\right ).\end{equation*}

Dividing both sides by $\left (\sum _{M\in \mathcal{M}^{\prime}} w(M)\right )^2$ , we obtain that

\begin{equation*}\mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {A}\square \mathcal {B} )\le \mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {A})\mathbb {P}(B^{\prime}(M^{\prime})\in \mathcal {B}).\end{equation*}

From Lemma 2.2, it follows that it is enough to prove that for any $i\in I^{\prime}$ , we have

(4) \begin{equation} \big|\big(\mathcal{M}_{\mathcal{A}\square \mathcal{B}}\times \mathcal{M}^{\prime}\big)\cap X_i\big|\le \big|\big(\mathcal{M}_{\mathcal{A}}\times \mathcal{M}_{\mathcal{B}}\big)\cap X_i\big|. \end{equation}

For a subset $\mathcal{F}$ of $2^{V^{\prime}}$ and $i\in I^{\prime}$ , we define

\begin{equation*}\mathcal {F}^i=\big\{\tau _i(C)\big|C\in Y_i^C\cap \mathcal {M}_{\mathcal {F}}\big\}=\big\{B(C)\cap U_i\big| C\in Y_i^C, B^{\prime}(C)\in \mathcal {F}\big\}.\end{equation*}

From Equation (1), it follows that $\big\{B^{\prime}(C)|C\in Y_i^C\big\}=\big\{B^{\prime}(D)|D\in Y_i^D\big\}$ . Therefore, $\mathcal{F}^i=\big\{\tau _i(D)|D\in Y_i^D\cap \mathcal{M}_{\mathcal{F}}\big\}$ . (Note that, even for an increasing $\mathcal{F}$ it might happen that $\mathcal{F}^i$ is not increasing.) For a subset $\mathcal{J}$ of $2^{U_i}$ , we define $\overline{\mathcal{J}}=\{U_i\backslash J|J\in \mathcal{J}\}$ .

Then

(5) \begin{align} |(\mathcal{M}_{\mathcal{A}}\times & \mathcal{M}_{\mathcal{B}})\cap X_i|\\&= \big|\big\{(C,D)\in Y_i^C\times Y_i^D\big| \tau _i(C)\in \mathcal{A}^i,\tau _i(D)\in \mathcal{B}^i,\tau _i(C)=U_i\backslash \tau _i(D) \big\}\big|\nonumber \\&= \big|\big\{(A,B)\in 2^{U_i}\times 2^{U_i}\big|A\in \mathcal{A}^i,B\in \mathcal{B}^i,A=U_i\backslash B \big\}\big|\nonumber \\&=\big|\mathcal{A}^i\cap \overline{\mathcal{B}^i}\big|.\nonumber \end{align}

Similarly,

(6) \begin{equation} \big|\big(\mathcal{M}_{\mathcal{A}\square \mathcal{B}}\times \mathcal{M}^{\prime}\big)\cap X_i\big|=\big|\big(\mathcal{A}\square \mathcal{B}\big)^i\big|. \end{equation}

Lemma 2.3. We have

\begin{equation*}(\mathcal {A}\square \mathcal {B})^i\subseteq \mathcal {A}^i\square \mathcal {B}^i.\end{equation*}

Proof. Let $F\in (\mathcal{A}\square \mathcal{B})^i$ , then $F=\tau _i(C)$ for some $C\in Y_i^C$ such that $B^{\prime}(C)\in \mathcal{A}\square \mathcal{B}$ . Since $\mathcal{A}$ and $\mathcal{B}$ are upward closed, there are disjoint sets $V_A\in \mathcal{A}$ and $V_B\in \mathcal{B}$ such that $B^{\prime}(C)=V_A\cup V_B$ . We define

\begin{equation*}U_A=\{v_{j,1}|\quad \big\{v_{j,0},v_{j,1}\big\}\cap V_A\neq \emptyset, j\in \{1,2,\ldots,k\}\}\end{equation*}

and

\begin{equation*}U_B=\{v_{j,1}|\quad \big\{v_{j,0},v_{j,1}\big\}\cap V_B\neq \emptyset, j\in \{1,2,\ldots,k\}\}.\end{equation*}

Since $V_A$ and $V_B$ are disjoint and $\big|B^{\prime}(C)\cap \big\{v_{j,0},v_{j,1}\big\}\big|=1$ for all $j$ , we obtain that $U_A$ and $U_B$ are disjoint.

Moreover, if for some $C^{\prime}\in Y_i^C$ , we have $\tau _i(C)\cap U_A=\tau _i(C^{\prime})\cap U_A$ , then $ V_A\subseteq B^{\prime}(C^{\prime})$ . Consequently $B^{\prime}(C^{\prime})\in \mathcal{A}$ and $\tau _i(C^{\prime})\in \mathcal{A}^i$ . The analogous statement is true for $V_B$ and $U_B$ . Therefore, the pair $U_A,U_B$ witnesses that $F=\tau _i(C)\in \mathcal{A}^i\square \mathcal{B}^i$ .

Recall the following theorem of Reimer [Reference Reimer2]. See also [Reference van den Berg and Jonasson4].

Theorem 2.1. (Reimer) Let $\mathcal{X}$ and $\mathcal{Y}$ be subsets of $2^U$ , where $U$ is a finite set. Then

\begin{equation*}|\mathcal {X}\square \mathcal {Y}|\le \big|\mathcal {X}\cap \overline {\mathcal {Y}}\big|.\end{equation*}

Combining Theorem 2.1 with Equations (5) and (6) and Lemma 2.3, we obtain that

\begin{align*} \big|\big(\mathcal{M}_{\mathcal{A}\square \mathcal{B}}\times \mathcal{M}^{\prime}\big)\cap X_i\big|=|(\mathcal{A}\square \mathcal{B})^i|\le |\mathcal{A}^i\square \mathcal{B}^i| \le \big|\mathcal{A}^i\cap \overline{\mathcal{B}^i}\big|=\big|\big(\mathcal{M}_{\mathcal{A}}\times \mathcal{M}_{\mathcal{B}}\big)\cap X_i\big|. \end{align*}

This proves Inequality (4).

2.3 The proof Corollary 1.5

Let $X_0=X\backslash Y$ and $Y_0=Y\backslash X$ . Clearly the events $X_0\subseteq B(M)$ and $Y_0\subseteq B(M)$ depend on disjoint sets. Theorem 1.4 gives us

\begin{align*} & \mathbb{P}(X_0\subseteq B(M)|X\cap Y\subseteq B(M)) \mathbb{P}(Y_0\subseteq B(M)|X\cap Y\subseteq B(M)) \\[3pt]& \quad\ge \mathbb{P}(X_0\subseteq B(M),Y_0\subseteq B(M)|X\cap Y\subseteq B(M)), \end{align*}

and this is equivalent with the statement of the corollary.

2.4 The proof Theorem 1.6

Let $t\gt 0$ , and set all the edge weights to be equal to $t$ . Let $M_t$ be the corresponding random matching. By Theorem 1.3, if $\mathcal{A}$ and $\mathcal{B}$ are increasing events, then

\begin{equation*}\mathbb {P}\big(B\big(M_t\big)\in \mathcal {A}\square \mathcal {B} \big)\le \mathbb {P}(B\big(M_t\big)\in \mathcal {A})\mathbb {P}\big(B\big(M_t\big)\in \mathcal {B}\big).\end{equation*}

Observe that

\begin{align*} \lim _{t\to \infty }\mathbb{P}\big(B\big(M_t\big)\in \mathcal{A}\big)&=\mathbb{P}(B(M)\in \mathcal{A}),\quad \lim _{t\to \infty }\mathbb{P}\big(B\big(M_t\big)\in \mathcal{B}\big)=\mathbb{P}(B(M)\in \mathcal{B})\\&\text{ and }\lim _{t\to \infty }\mathbb{P}\big(B\big(M_t\big)\in \mathcal{A}\square \mathcal{B}\big)=\mathbb{P}(B(M)\in \mathcal{A}\square \mathcal{B}). \end{align*}

Thus, the statement follows.