Operate in ZFC. Can we find a function-class $\phi$ whose domain is the class of ordinals such that the following properties hold?

 - If $x \in \phi(\alpha)$, then either $x \in \mathbb{N}$ or there exists some ordinal $\beta < \alpha$ with $\phi(\beta) = x$;
 - If $\phi(\alpha) \subseteq \phi(\beta)$, then $\alpha = \beta$.

The first of these conditions equivalently states that the image of $\phi$ is a transitive set, except that the natural numbers are treated as urelements, and with the constraint that $\phi(\beta) \in \phi(\alpha) \implies \beta \in \alpha$.

The second condition means that $\phi$ is injective and its image is an antichain under inclusion.

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We can construct such a function-class if we assume additional axioms, such as the existence of no inaccessible cardinals. In particular, the following construction will work:

 - $\phi(0) := \{ 1 \}$
 - $\phi(\alpha + 1) := \{ 2, \phi(\alpha) \}$ for every $\alpha$
 - $\phi(\omega) := \{ 3 \}$
 - $\phi(\beta) := \{ 4, \phi(\textrm{cf}(\beta))\} \cup \{ \phi(\gamma) : \gamma \in C_{\beta} \}$ (where $C_{\beta}$ is a cofinal subset of $\beta$ with order-type $\textrm{cf}(\beta)$ such that no element of $C_{\beta}$ is less than or equal to $\textrm{cf}(\beta)$), for singular limit ordinals $\beta$
 - $\phi(\omega_{\alpha+1}) := \{ 5, \phi(\alpha) \}$ for every $\alpha$

The first of these rules deals with the zero ordinal, and the second deals with successor ordinals. The third of these handles the special case $\omega$. The fourth handles limit ordinals which are not regular ordinals. The fifth handles initial ordinals of successor cardinals. This construction, however, does not define an image if there are inaccessible cardinals (whose initial ordinals do not fit the form for either the fourth or fifth rules).

**Proof:** We can verify transitivity since every element of $\phi(\alpha)$ is, by definition, either a natural number or a $\phi(\beta)$ for some earlier $\beta$. Verifying the antichain property is more complicated, but it boils down to the following:

 - Clearly $\phi(\alpha) \subseteq \phi(\beta)$ means that their unique urelements must agree, which means $\alpha$ and $\beta$ were processed by the same rule (out of the five provided).
 - The first and third rules each only process one ordinal, and the second and fifth are clearly injective as well.
 - For the fourth rule, we can recover $\textrm{cf}(\alpha)$ and $C_{\alpha}$ from $\phi(\alpha)$ by removing the urelement, inverting $\phi$, and separating the preimage into its first element and the remaining elements. If $\phi(\alpha) \subseteq \phi(\beta)$, it thus follows that $C_{\alpha} \subseteq C_{\beta}$, and that they have the same order-type (which is a regular ordinal), which implies they have the same limit, so $\alpha = \beta$.

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This works when there are no inaccessible cardinals, and one can introduce further rules to provide a construction which works under the weaker hypothesis that there are no hyper-inaccessible cardinals. Is there a construction which does not depend on additional axioms beyond ZFC?