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Main Authors: Hennick, Max, Corlouer, Guillaume
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.29805
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author Hennick, Max
Corlouer, Guillaume
author_facet Hennick, Max
Corlouer, Guillaume
contents A key problem in the modern study of AI is predicting and understanding emergent capabilities in models during training. Inspired by methods for studying reactions in quantum chemistry, we present the ``2-datapoint reduced density matrix". We show that this object provides a computationally efficient, unified observable of phase transitions during training. By tracking the eigenvalue statistics of the 2RDM over a sliding window, we derive two complementary signals: the spectral heat capacity, which we prove provides early warning of second-order phase transitions via critical slowing down, and the participation ratio, which reveals the dimensionality of the underlying reorganization. Remarkably, the top eigenvectors of the 2RDM are directly interpretable making it straightforward to study the nature of the transitions. We validate across four distinct settings: deep linear networks, induction head formation, grokking, and emergent misalignment. We then discuss directions for future work using the 2RDM.
format Preprint
id arxiv_https___arxiv_org_abs_2603_29805
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle From Density Matrices to Phase Transitions in Deep Learning: Spectral Early Warnings and Interpretability
Hennick, Max
Corlouer, Guillaume
Machine Learning
Artificial Intelligence
A key problem in the modern study of AI is predicting and understanding emergent capabilities in models during training. Inspired by methods for studying reactions in quantum chemistry, we present the ``2-datapoint reduced density matrix". We show that this object provides a computationally efficient, unified observable of phase transitions during training. By tracking the eigenvalue statistics of the 2RDM over a sliding window, we derive two complementary signals: the spectral heat capacity, which we prove provides early warning of second-order phase transitions via critical slowing down, and the participation ratio, which reveals the dimensionality of the underlying reorganization. Remarkably, the top eigenvectors of the 2RDM are directly interpretable making it straightforward to study the nature of the transitions. We validate across four distinct settings: deep linear networks, induction head formation, grokking, and emergent misalignment. We then discuss directions for future work using the 2RDM.
title From Density Matrices to Phase Transitions in Deep Learning: Spectral Early Warnings and Interpretability
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.29805