A combinatorial characterization of Kim's lemma for pairs of bi-invariant types
Abstract
We give a combinatorial consistency-inconsistency configuration that is equivalent to the failure of the following form of Kim's lemma for a given $k$: $(\star)$ For any set of parameters $A$, formula $\varphi(x,b)$, and $A$-bi-invariant types $p$ and $q$ extending $\mathrm{tp}(b/A)$, if $\varphi(x,b)$ $k$-divides along $p$, then it divides along $q$. We then give an equivalent technical variant of $(\star)$ that is non-trivial over arbitrary invariance bases. We also show that the failure of weaker versions of $(\star)$ entails the existence of stronger combinatorial configurations, the strongest of which can be phrased in terms of families of parameters indexed by arbitrary cographs (i.e., $P_4$-free graphs). Finally, we show that if there is an array $(b_{i,j} : i,j < \omega)$ of parameters such that $\{\varphi(x,b_{i,j}) : (i,j) \in C\}$ is consistent whenever $C \subseteq \omega^2$ is a chain (in the product partial order) and $k$-inconsistent whenever $C$ is an antichain, then there is a model $M$, parameter $b$, and $M$-coheirs $p,q \supset \mathrm{tp}(b/M)$ such that $q^{\otimes \omega}$ is an $M$-heir-coheir and $\varphi(x,b)$ $k$-divides along $p$ but does not divide along $q$. In doing so, we also show that this configuration entails the failure of generic stationary local character under the assumption of $\mathsf{GCH}$.