The Concept Allocation Zone: Tracking How Concepts Form Across Transformer Depth
Abstract
Concept formation in transformer language models is depth-extended, not a single-layer event: concepts emerge gradually across a contiguous region of the residual stream. Mechanistic interpretability methods identify the single layer of peak class separation -- the "best layer" -- capturing a snapshot rather than the process itself. We introduce the Concept Allocation Zone (CAZ): the depth interval within which a concept becomes measurably separable, the region allocated to its geometric expression. We formalize the CAZ through three layer-wise metrics (Separation, Concept Coherence, Concept Velocity) and derive principled boundary detection without manual layer sweeps. A CAZ is not a concept: it is the depth region within which the model organizes its geometry to make a concept separable. A single concept typically participates in multiple CAZes; multiple concepts may share one. Empirical validation across 34 models from 8 architectural families and 7 concepts reveals that the separation curve S(l) is frequently multimodal. A scored detector uncovers "gentle CAZes" -- subtle allocation regions invisible to standard peak detection but causally active in 93-100% of cases under ablation (16 of 34 models; 26 in the companion validation paper). The framework generates seven testable predictions; four yield clear verdicts (two not supported, one partially supported, one supported), one had its precondition invalidated by the data, and two are underpowered -- with cross-architecture alignment confirmed as depth-matched rather than monolithic under leave-one-concept-out cross-validation. Reference implementation: rosetta_tools v1.3.1 (doi:10.5281/zenodo.20361433).
Keywords
Cite
@article{arxiv.2605.24856,
title = {The Concept Allocation Zone: Tracking How Concepts Form Across Transformer Depth},
author = {James Henry},
journal= {arXiv preprint arXiv:2605.24856},
year = {2026}
}
Comments
34 models, 8 architectural families, 7 concepts. Companion papers: GEM (arXiv forthcoming), CAZ Validation (arXiv forthcoming), PRH Validation (arXiv forthcoming). Code: https://github.com/jamesrahenry/Rosetta_Tools