Deducing the Density Hales-Jewett Theorem from an infinitary removal lemma

We offer a new proof of Furstenberg and Katznelson's density version of the Hales-Jewett Theorem: For any $\delta > 0$ there is some $N_0 \geq 1$ such that whenever $A \subseteq [k]^N$ with $N \geq N_0$ and $|A|\geq \delta k^N$, $A$ contains a \textbf{combinatorial line}: that is, for some $I \subseteq [N]$ nonempty and $w_0 \in [k]^{[N]\setminus I}$ we have A \supseteq \{w: w|_{[N]\setminus I} = w_0, w|_I = \rm{const.}\}. Following Furstenberg and Katznelson, we first show that this result is equivalent to a `multiple recurrence' assertion for a class of probability measures enjoying a certain kind of stationarity. However, we then give a quite different proof of this latter assertion through a reduction to an infinitary removal lemma in the spirit of Tao's work on infinite random hypergraphs (and also its recent re-interpretation in a new proof of the multidimensional Szemeredi Theorem by the present author). This reduction is based on a structural analysis of these stationary laws closely analogous to the classical representation theorems for various partial exchangeable stochastic processes in the sense of Hoover, Aldous and Kallenberg. However, the underlying combinatorial arguments used to prove this theorem are rather different from those required to work with exchangeable arrays, and involve crucially an observation that arose during ongoing work by a collaborative team of authors to give a purely finitary proof of the above theorem.