Add chained-seam findings note (medial pigeonhole)

Write up the R_T coupling, the uniform-family result (feasible n=9, infeasible n=12 via empty size-7 universal, 0001112 blocked 210/211), and the open threads. Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
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 # Chained seams: the medial pigeonhole, located
 Companion to the interface-alphabet results (`kempe_interface_admissibility_probe.py`,
 `kempe_tile_overlap_probe.py`). This note pursues the paper's §6 *medial pigeonhole
 programme* — the restriction relation `R_T` between a tire's outer and inner boundary
 states, and the open *chain-pigeonhole conjecture* — at the data level.
 Scripts: `kempe_transfer_relation_probe.py`, `kempe_uniform_family_probe.py`.
 ## Background
 A nested chain `T_0 ⊃ T_1 ⊃ …` glues into a proper 3-colouring of `M(G)` iff
 consecutive boundary states match: `inner-state(T_i) = outer-state(T_{i+1})`
 (compatible family, paper Prop "gluing criterion"). Boundary states are necklaces
 (colours permuted, boundary walk rotated/reflected). The restriction relation
 ```
 R_T ⊆ outer-states × inner-states
 ```
 records which (outer, inner) boundary-state pairs one Kempe-balanced colouring of `T`
 realises jointly. The chain-pigeonhole conjecture asks whether nested `R_T`'s can ever
 compose to empty.
 Established earlier: the realised boundary alphabet (each side) is exactly the full
 parity-admissible set, identical inner vs outer, `n`-independent (n=9, n=12, m=3..8);
 and every *pair* of tiles overlaps, so single seams never dead-end.
 ## Finding 1 — `R_T` is genuinely coupled
 `R_T` is **not** a product of its projections: a tile's inner boundary necklace
 constrains its outer one. Seen at n=9 in the `(p,q) = (4,5)` and `(5,4)` size classes
 (`product? = False`), and broadly at n=12. So "every seam individually realisable"
 does **not** trivially pass through a tile.
 ## Finding 2 — the uniform shortcut works at n=9, breaks at n=12
 Question: is there one boundary state `σ_m` per level-cycle *size* that threads every
 tile simultaneously (outer face and every inner face)? If so, painting every level
 cycle `σ_m` glues any tree with no pigeonhole.
 - **n=9: FEASIBLE.** Unique universal per size (`|D[m]| = 1`), and notably *not*
  monochromatic — the balanced-block necklaces
  ```
  σ3 = 012   σ4 = 0011   σ5 = 00012   σ6 = 000011
  ```
  threads all 66 tiles. (Caveat: n=9 has **no** branching tiles.)
 - **n=12: INFEASIBLE.** 1237 tiles (1029 bite, 175 genuinely branching). The CSP fails
  for one sharp reason: **size-7 seams admit no universal state** (`|D[7]| = 0`). The
  211 size-7 boundaries realise all 10 admissible necklaces between them, but their
  intersection is empty — the near-universal `0001112` lands on **210 of 211**,
  blocked by a single tile.
 Per-size universal domain sizes at n=12: `3:1  4:1  5:1  6:2  7:0  8:4  9:1`.
 ## Finding 3 — interpretation
 Universals vanish as the tile population grows (more boundaries of a given size → more
 sets to intersect → empty), so the "paint every seam identically" shortcut is doomed
 at scale; the per-interface pigeonhole choice is genuinely necessary. **But this is
 not an obstruction to gluing** — pairwise overlap still always holds, so chains still
 glue by choosing states per interface. We have *located why the conjecture is hard*:
 the difficulty lives in the non-uniform, branch-coupled selection across the tree,
 exactly where the paper's pigeonhole sits — not in any single seam or a uniform
 assignment.
 ## Open threads
 - **Odd-size seams are the pressure point.** Uniformity first fails at size 7 (odd);
  small odd sizes 3, 5 kept unique universals. Does every large odd size lose its
  universal as `n` grows? (tracked below / in follow-up).
 - **The 210/211 near-miss.** A single tile blocks the size-7 universal — identifying
  the "universal-breaker" tiles may expose the combinatorial core.
 - **Branch-tree composition.** n=12 has 175 true branching tiles; composing `R_T`
  along actual trees (not just per-size uniformity) is the conjecture proper.