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Main Author: Venkatesh, Sohan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.08853
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author Venkatesh, Sohan
author_facet Venkatesh, Sohan
contents Mechanistic interpretability assumes that circuit analysis becomes harder as models scale. We challenge this assumption by showing that the attention architecture matters more than parameter count. Studying three circuit types across Pythia and Qwen2.5, we find that grouped query attention produces circuits that are far more concentrated and mechanistically stable than standard multi-head attention at comparable scales. The same concentration pattern holds across indirect object identification, induction heads, and factual recall. Within a single architecture family (Qwen2.5), factual recall circuits undergo a discrete phase transition above a critical scale, collapsing to a single bottleneck rather than degrading gradually. These findings suggest that some architectural choices make large models more tractable to study and that interpretability difficulty is not a fixed consequence of model size.
format Preprint
id arxiv_https___arxiv_org_abs_2605_08853
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Architecture, Not Scale: Circuit Localization in Large Language Models
Venkatesh, Sohan
Computation and Language
Mechanistic interpretability assumes that circuit analysis becomes harder as models scale. We challenge this assumption by showing that the attention architecture matters more than parameter count. Studying three circuit types across Pythia and Qwen2.5, we find that grouped query attention produces circuits that are far more concentrated and mechanistically stable than standard multi-head attention at comparable scales. The same concentration pattern holds across indirect object identification, induction heads, and factual recall. Within a single architecture family (Qwen2.5), factual recall circuits undergo a discrete phase transition above a critical scale, collapsing to a single bottleneck rather than degrading gradually. These findings suggest that some architectural choices make large models more tractable to study and that interpretability difficulty is not a fixed consequence of model size.
title Architecture, Not Scale: Circuit Localization in Large Language Models
topic Computation and Language
url https://arxiv.org/abs/2605.08853