Prior proofs gave extremely weak bounds (e.g., Ackermann-type or tower-of-exponentials). Polymath 6.1 sought to reduce the tower height.
Existing approaches involved iterating a “density increment” step, but each step reduced the dimension dramatically. The key polynomial helped track density increments more efficiently. 4. Specifics of the “Key Polynomial” While Polymath 6.1 did not name one single polynomial “the key,” the following polynomial (or its variants) played the central role:
For precise algebraic form, consult the (section “Key lemma” or “Key polynomial”) or the final paper: “Density Hales-Jewett and Moser numbers” (2012). polymath 6.1 key
or more combinatorially:
Let $x_1, x_2, \dots, x_n$ be variables in $0,1,2$ (or $\mathbbF_3$). Consider: Prior proofs gave extremely weak bounds (e
[ P(\mathbfx) = \sum_i=1^n \omega^x_i \quad \text(where $\omega$ is a primitive 3rd root of unity) ]
[ \textKey function: f(x) = \text(# of 0's) - \text(# of 1's) \quad \textmod something? ] The key polynomial helped track density increments more
But the actual breakthrough came from (e.g., $\mathbbF_3^n$). A specific “key polynomial” used in the density increment argument was:
[ Q(x) = \sum_i<j (x_i - x_j)^2 ]