Fact 1.3. $\mathsf {ZFC}$ without the Axiom of Foundation proves the equiconsistency of $\mathsf {ZFC}$ and $\mathsf {ZFA}$ .

Proof In one direction, from a model of $\mathsf {ZFA}$ one obtains one of $\mathsf {ZFC}$ by restricting to the well-founded sets. In the other direction, see [Reference Forti and Honsell9, Theorem 4.2] for a class theory version, or [Reference Aczel1, Chapter 3] for the $\mathsf {ZFC}$ statement.

Notation. By graph we mean a first-order structure with a single relation that is binary and symmetric (it is not required to be irreflexive).

Assumption 2.1. The ambient metatheory is $\mathsf {ZFC}+\operatorname {\mathrm {Con}}(\mathsf {ZFC})$ .

Proof Work in M until further notice. Let G be a graph in M, say in the language

. Let $\kappa $ be its cardinality, and assume up to a suitable isomorphism that $\operatorname {\mathrm {dom}} G=\kappa $ . In particular, note that every element of $\operatorname {\mathrm {dom}} G$ is a well-founded set. Consider the flat system

Let $s\colon x_i\mapsto a_i$ be a solution to the system. If $i\ne j$ , then

, and therefore s is injective. Observe that:

1. (i) since R is symmetric, we have $a_i\in a_j\in a_i\iff G\vDash R(i,j)$ , and

2. (ii) for all $b\in M$ and all $i\in \kappa $ , we have $b\in a_i\in b$ if and only if there is $j<\kappa $ such that $b=a_j$ and $G\vDash R(i,j)$ .

Now work in the ambient metatheory. Consider the M-set

By (i) above, $(H, D^{M_1}\upharpoonright H)$ is isomorphic to G and, by (ii) above, H is a union of regions of M.

Proof Let C be a connected component of a graph G in M. By Proposition 3.3 there is an isomorphic copy H of G that is a union of regions of M, hence, in particular, of connected components of $M_1$ . Clearly, one of the connected components of H is isomorphic to C.

In the other direction, let $a\in M_1$ and consider its connected component. Inside M, let G be the region of a. Using Remark 3.2 it is easy to see that $(G, D\upharpoonright G)$ is a graph in M, and one of its connected components is isomorphic to the connected component of a in $M_1$ .

For the last part of the conclusion take, inside M, disjoint unions of copies of a given graph.

Proof Let G be a graph in M, say in the language . Assume without loss of generality that G has no isolated vertices, and that $\operatorname {\mathrm {dom}} G$ equals its cardinality $\kappa $ . For each $i\in \kappa $ choose $a_i\subseteq \kappa $ that has foundational rank $\kappa $ in M, e.g., let . Let and note that, since no vertex of G is isolated, $b_j$ is non-empty, and thus has rank $\kappa +1$ . Define $\pi \colon M\to M$ to be the permutation swapping each $a_i$ with the corresponding $b_i$ and fixing the rest of M. Let N be the structure with the same domain as M, but with membership relation defined as

$$\begin{align*}N\vDash x\in y\iff M\vDash x\in \pi(y). \end{align*}$$

By [Reference Rieger15, Section 3]Footnote ¹ , N is a model of $\mathsf {ZFC}$ without Foundation. To check that $N_1$ is as required, first observe that

$$\begin{align*}N\vDash a_i\in a_j\iff M\vDash a_i\in \pi(a_j)=b_j\iff G\vDash R(i,j) \end{align*}$$

so , equipped with the restriction of $D^{N_1}$ , is isomorphic to G. To show that there are no other D-edges in $N_1$ , assume that $N_1\vDash D(x,y)$ , and consider the following three cases (which are exhaustive since D is symmetric).

1. (i) x and y are both fixed points of $\pi $ . This contradicts Foundation in M.

2. (ii) $y=a_i$ for some i, so $N\vDash x\in a_i$ ; hence $M\vDash x\in \pi (a_i)=b_i$ . Then $x=a_j$ for some j by construction.

3. (iii) $y=b_i$ for some i. From $N\vDash x\in b_i$ we get $M\vDash x\in a_i\subseteq \kappa $ ; thus x has rank strictly less than $\kappa $ . Therefore, x is not equal to any $a_j$ or $b_j$ ; hence $\pi (x)=x$ . Again by rank considerations, it follows that $M\vDash b_i\notin x=\pi (x)$ , so $N\vDash b_i\notin x$ , a contradiction.

Proof It suffices to find a certain finite graph as a connected component of $M_1$ , so this follows from Proposition 3.3 (or directly from [Reference Adam-Day and Cameron2, Theorem 4]).

Proof If $A, B$ are distinct subsets of and, without loss of generality, there is an , then $\beta _A$ contradicts $\beta _B$ because $\beta _A(y)\vdash \exists x_n\; (\varphi _n(x_n)\land D(y,x_n))$ and $\beta _B(y)\vdash \neg \exists x_n\; (\varphi _n(x_n)\land D(y,x_n))$ .

To show that each $\beta _A$ is consistent it is enough, by compactness, to show that if $A_0$ is a finite subset of A and $A_1$ is a finite subset of then there is some $b\in M$ with a D-edge to an n-flower for every $n\in A_0$ and no D-edges to n-flowers whenever $n\in A_1$ . Any $A_0$ -bouquet will satisfy these requirements and, by Lemma 4.2, an $A_0$ -bouquet exists inside $M_1$ .

For the last part, note that all the theories at hand are complete (in different languages), and whether or not an intersection of definable sets is empty does not change after adding more definable sets.

Fact 4.4. Every partial type over $\emptyset $ of a countable theory can be realised in a countable model.

Proof Consider the pairwise contradictory partial types $\beta _A$ . By Fact 4.4, $\operatorname {\mathrm {Th}}(M)$ has $2^{\aleph _0}$ distinct countable models, as each of them can only realise countably many of the $\beta _A$ . The reducts to $L_1$ (resp. $L_0$ ) of models realising different subsets of are still non-isomorphic, since the $\beta _A$ are partial types in the language $L_1$ .

Proof Note that the class of graphs in M is closed under the operations of removing a point or adding one and connecting it to everything. Now apply Proposition 3.3.

Fact 5.6. Every $L_{\mathsf {NBG}}$ -structure N is interpretable in a graph $N'$ . Moreover, for every $L_{\mathsf {NBG}}$ -sentence $\theta $ there is an $L_1$ -sentence $\theta '$ such that:

1. 1. $\theta $ is consistent if and only if $\theta '$ is, and

2. 2. for every $L_{\mathsf {NBG}}$ -structure N we have $N\vDash \theta \iff N'\vDash \theta '$ .

Proof Apply Lemma 5.5 to .

Proof If $\theta $ is the conjunction of a finite fragment of $\mathsf {ZFC}$ , it is well-known that $\mathsf {ZFA}\vdash \operatorname {\mathrm {Con}}(\theta )$ . Since a model of $\theta $ is a digraph, we can apply Corollary 5.7. If a witnesses the outermost existential quantifier in $\mu (\theta ')$ , then $\theta $ is interpretable with parameter a.

Fact 5.9 Rosser’s Theorem

There is a $\Pi ^0_1$ arithmetical statement $\psi $ that is independent of $\mathsf {ZFA}$ .

Fact 5.10. Let $\psi $ be a $\Pi ^0_1$ arithmetical statement. There is another arithmetical statement $\widetilde \psi $ such that $\mathsf {ZFA}\vdash \psi \leftrightarrow \operatorname {\mathrm {Con}}(\mathsf {NBG}^-+\widetilde \psi )$ .

Proof Let $\psi $ be given by Rosser’s Theorem, and let $\widetilde \psi $ be given by Fact 5.10 applied to $\psi $ . Apply Corollary 5.7 to .

Proof We are asking whether there is any $M\vDash T\cup \operatorname {\mathrm {Th}}(N)$ , so it is enough to show that the latter theory is consistent. If not, there is an $L_1$ -formula $\varphi \in \operatorname {\mathrm {Th}}(N)$ such that $T\vdash \neg \varphi $ . In particular, since $\neg \varphi \in L_1$ , we have that $\operatorname {\mathrm {Th}}(K_1)\vdash \neg \varphi $ , and this contradicts that $N\vDash \operatorname {\mathrm {Th}}(K_1)$ .

Proof This is standard, see, e.g., [Reference Ebbinghaus and Flum6, Proposition 2.3.10].

Proof For statements about graphs, the equivalence of 2 and 3 follows from Lemma 5.5. For statements in other languages, it is enough to interpret them in graphs using [Reference Hodges10, Theorem 5.5.1].

For the equivalence of 1 and 2, we show that for every $n\in \omega $ the Ehrenfeucht–Fraïssé game between $M_1$ and $N_1$ of length n is won by the Duplicator, by describing a winning strategy. The idea behind the strategy is the following. Recall that, for every finite relational language and every k, there is only a finite number of $\equiv _{k}$ -classes, each characterised by a single sentence (see, e.g., [Reference Ebbinghaus and Flum6, Corollary 2.2.9]). After the Spoiler plays a point a, the Duplicator replicates the $\equiv _k$ -class of the region of a using Lemma 5.5.

Fix the length n of the game and denote by $a_1,\ldots ,a_{m}\in M_1$ and $b_1,\ldots ,b_{m}\in N_1$ the points chosen at the end of turn m. The Duplicator defines, by simultaneous induction on m, sets $G^{m}_0\subseteq M_1$ and $H^{m}_0\subseteq N_1$ , and makes sure that they satisfy the following conditions.

1. (C1) $a_1,\ldots ,a_m\in G^m_0$ and $b_1,\ldots ,b_m \in H^m_0$ .

2. (C2) $G^m_0$ and $H^m_0$ are unions of regions of M and N respectively.

3. (C3) $G_0^m$ and $H_0^m$ are respectively an M-set and an N-set.

4. (C4) When $G^m_0$ and $H^m_0$ are equipped with the $L_1$ -structures induced by M and N respectively, we have $(G^m_0,a_1,\ldots ,a_m)\equiv _{n-m} (H^m_0, b_1,\ldots ,b_m)$ .

Before the game starts (‘after turn $0$ ’) we set $G^0_0=H^0_0=\emptyset $ and all conditions trivially hold. Assume inductively that they hold after turn $m-1$ . We deal with the case where the Spoiler plays $a_m\in M_1$ ; the case where the Spoiler plays $b_m \in N_1$ is symmetrical.

Let $G^{m}_1$ be the region of $a_m$ in M. If $G_1^m\subseteq G_0^{m-1}$ then, since by inductive hypothesis condition (C4) held after turn $m-1$ , the Duplicator can find $b_m\in H_0^{m-1}$ such that $(G_0^{m-1},a_0,\ldots ,a_m)\equiv _{n-m}(H_0^{m-1}, b_0,\ldots ,b_m)$ . It is then clear that all conditions hold after setting $G_0^m=G_0^{m-1}$ and $H_0^m=H_0^{m-1}$ .

Otherwise, by (C2), we have $G^m_1\cap G^{m-1}_0=\emptyset $ . Let $\varphi $ characterise the $\equiv _{n-m+1}$ -class of $G^m_1$ . Note that, if $n-m+1\ge 2$ , then $\varphi \in \Phi $ automatically. Otherwise, replace $\varphi $ with $\varphi \land \forall x\forall y\; (D(x,y)\rightarrow D(y,x))$ . By Remark 3.2, $G^m_1$ is an M-set, hence $M\vDash \operatorname {\mathrm {Con}}(\varphi )$ . By Lemma 5.5 and assumption, there is a union $H^m_1$ of regions of N which is an N-set and such that $G^m_1\equiv _{n-m+1} H^m_1$ . By inductive hypothesis, $H_0^{m-1}$ is also an N-set by (C3). Therefore, up to writing a suitable flat system in N, we may replace $H_1^m$ with an isomorphic copy that is still a union of regions and an N-set, but with $H_1^m\cap H_0^{m-1}=\emptyset $ .

Let $b_m\in H_1^m$ be the choice given by a winning strategy for the Duplicator in the game of length $n-m+1$ between $G_1^m$ and $H_1^m$ after the Spoiler plays $a_m\in G_1^m$ as its first move. Set $G^m_0=G^{m-1}_0\cup G^m_1$ and $H^m_0=H^{m-1}_0\cup H^m_1$ . Note that $G^{m-1}_0, G^m_1, H^{m-1}_0, H^m_1$ are all unions of regions and M-sets or N-sets; hence (C2) and (C3) hold (and (C1) is clear). Moreover both unions are disjoint, so the hypotheses of Lemma 5.13 are satisfied and $(G^m_0,a_1,\ldots ,a_m) \equiv _{n-m} (H^m_0, b_1,\ldots ,b_m)$ , i.e., (C4) holds.

To show that this strategy is winning, note that the outcome of the game only depends on the induced structures on $a_1,\ldots ,a_n$ and $b_1,\ldots ,b_n$ at the end of the final turn. These do not depend on what is outside $G_0^n$ and $H_0^n$ since they are unions of regions, hence unions of connected components. As (C4) holds at the end of turn n, the structures induced on $a_1,\ldots ,a_n$ and $b_1,\ldots ,b_n$ are isomorphic.

Proof Let $N'$ satisfy the axiomatisation above. Since N and $N'$ are models of $\operatorname {\mathrm {Th}}(K_1)$ we may, by Proposition 5.12, replace them with D-graphs $M_1\equiv N$ and $M_1'\equiv N'$ of models of $\mathsf {ZFA}$ . By Theorem 5.14 $M_1\equiv M_1'$ .

Proof Let N be given by Theorem 5.16 and . Now observe that, as follows easily from Proposition 3.3, any reduct to $L_1$ of a model of $\mathsf {ZFA}$ has a connected component of infinite diameter.

Proof of Theorem 5.16

Up to passing to a countable elementary substructure, we may assume that M itself is countable. Let N be obtained from $M_0$ by removing all points whose connected component in $M_1$ has infinite diameter. We show that $M_0\equiv N$ by exhibiting, for every n, a sequence $(I_j)_{j\le n}$ of non-empty sets of partial isomorphisms between $M_0$ and N with the back-and-forth property (see [Reference Ebbinghaus and Flum6, Definition 2.3.1 and Corollary 2.3.4]). The idea is to adapt the proof of [Reference Otto14, Lemma 2.2.7] (essentially Hanf’s Theorem) by considering the Gaifman balls with respect to $L_1$ , while requiring the partial isomorphisms to preserve the richer language $L_0$ .

On an $L_0$ -structure A, consider the distance given by the graph distance in the reduct $A\upharpoonright L_1$ (where $d(a,b)=\infty $ iff $a,b$ lie in distinct connected components). If $a_1,\ldots ,a_k\in A$ and $r\in \omega $ , denote by $\operatorname {\mathrm {dom}}(B(r,a_1,\ldots ,a_k))$ the union of the balls of radius r (with respect to d) centred on $a_1,\ldots ,a_k$ . Equip $\operatorname {\mathrm {dom}}(B(r,a_1,\ldots ,a_k))$ with the $L_0$ -structure induced by A, then expand to an -structure $B(r, a_1,\ldots ,a_k)$ by interpreting each constant symbol $c_i$ with the corresponding $a_i$ . We stress that, even though $B(r, a_1,\ldots ,a_k)$ carries an -structure, and we consider isomorphisms with respect to this structure, the balls giving its domain are defined with respect to the distance induced by $L_1$ alone.

Set

and fix n. Define

, where $\emptyset $ is thought of as the empty partial map $M_0\to N$ . For $j<n$ , let $I_j$ be the following set of partial maps $M_0\to N$ :

We have to show that for every map $a_1,\ldots ,a_k\mapsto b_1,\ldots ,b_k$ in $I_{j+1}$ and every $a\in M_0$ [resp. every $b\in N$ ] there is $b\in N$ [resp. $a\in M_0$ ] such that $a_1,\ldots ,a_k, a\mapsto b_1,\ldots ,b_k, b$ is in $I_j$ .

Denote by $\iota $ an isomorphism $B(r_{j+1}, a_1,\ldots ,a_k)\to B(r_{j+1}, b_1,\ldots ,b_k)$ and let $a\in M_0$ . If a is chosen in $B(2\cdot r_j+1, a_1,\ldots ,a_k)$ , then by the triangle inequality and the fact that $2\cdot r_j+1+r_j=r_{j+1}$ we have $B(r_j, a)\subseteq B(r_{j+1}, a_1,\ldots ,a_k)$ , and we can just set .

Otherwise, again by the triangle inequality, $B(r_j, a)$ and $B(r_{j}, a_1,\ldots ,a_k)$ are disjoint and there is no D-edge between them. Note, moreover, that they are M-sets. This allows us to write a suitable flat system, which will yield the desired b.

Working inside M, for every $d\in B(r_j, a)$ choose a well-founded set $h_d$ such that for all $d,d_0,d_1\in B(r_j,a)$ we have:

1. (H1) $h_{d_0}\notin h_{d_1}$ ,

2. (H2) if $d_0\ne d_1$ then $h_{d_0}\ne h_{d_1}$ ,

3. (H3) $h_d\notin B(r_{j}, b_1,\ldots ,b_k)$ ,

4. (H4) $h_d\notin \bigcup B(r_{j}, b_1,\ldots ,b_k)$ , and

5. (H5) $h_d\notin \bigcup \bigcup B(r_{j}, b_1,\ldots ,b_k)$ .

Let

be a set of indeterminates. Define

and consider the flat system

(*)

Intuitively, the terms $P_d$ ensure that the image of a solution is an isomorphic copy of $B(r_j, a)$ , while the terms $Q_d$ create the appropriate S-edges between the image and $B(r_j,b_1,\ldots ,b_k)$ (note that we do not need any D-edges because there are none between $B(r_j,a)$ and $B(r_j, a_1,\ldots ,a_k)$ ). The

are needed for bookkeeping reasons, in order to avoid pathologies. We now spell out the details; keep in mind that each $P_d$ consists of indeterminates, and each $Q_d$ is a subset of $B(r_j, b_1,\ldots ,b_k)$ .

Let s be a solution of (*), guaranteed to exist by $\mathsf {AFA}$ . By (H1) and the fact that each member of $\operatorname {Im}(s)$ contains some $h_d$ , we have . Using this together with (H2) and (H3) we have $h_d\in s(x_e)\iff d=e$ ; hence s is injective.

Let and . By (H4) we have that $\operatorname {Im}(s)$ does not intersect $B(r_j, b_1,\ldots ,b_k)$ , and we already showed that it does not meet . By looking at (*) and at the definition of the terms $P_d$ , we have that $\operatorname {Im}(s)=B(r_j, b)$ and that $s'$ is an isomorphism $B(r_j,a)\to B(r_j, b)$ .

Note that the only D-edges involving points of $\operatorname {Im}(s)$ can come from the terms $P_d$ : the $h_d$ are well-founded, and there are no $g\in \operatorname {Im}(s)$ and $\ell \in B(r_{j}, b_1,\ldots ,b_k)$ such that $g\in \ell $ , since g contains some $h_d$ but this cannot be the case for any element of $\ell $ because of (H5). Hence $\operatorname {Im}(s)$ is a connected component of $M_1$ and it has diameter not exceeding $2\cdot r_j$ , so is included in N.

Set . This map is injective because it is the union of two injective maps whose images $B(r_j, b)$ and $B(r_j, b_1,\ldots ,b_k)$ are, as shown above, disjoint. Moreover, there are no D-edges between $B(r_j, b)$ and $B(r_j, b_1,\ldots ,b_k)$ , since the former is a connected component of $M_1$ . By inspecting the terms $Q_d$ , we conclude that $\iota '$ is an isomorphism $B(r_j, a_1,\ldots ,a_k,a)\to B(r_j, b_1,\ldots ,b_k,b)$ , and this settles the ‘forth’ case.

The proof of the ‘back’ case, where we are given $b\in N$ and need to find $a\in M_0$ , is analogous (and shorter, as we do not need to ensure that the new points are in N): we can consider statements such as $e\in d$ when $e,d\in N$ since the domain of the $L_0$ -structure N is a subset of M.

Problems. We leave the reader with some open problems.

1. 1. Axiomatise the theory of D-graphs of models of $\mathsf {ZFA}$ .

2. 2. Axiomatise the theory of SD-graphs of models of $\mathsf {ZFA}$ .

3. 3. Characterise the completions of the theory of SD-graphs of models of $\mathsf {ZFA}$ .