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Main Authors: Bran, Andres M, Xie, Tong, Pranesh, Shai, Meng, Jeffrey, Nguyen, Xuan Vu, Goumaz, Jeremy, Segura, David Ming, Xu, Ruizhi, Zhou, Dongzhan, Zhang, Wenjie, Hoex, Bram, Schwaller, Philippe
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.21231
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author Bran, Andres M
Xie, Tong
Pranesh, Shai
Meng, Jeffrey
Nguyen, Xuan Vu
Goumaz, Jeremy
Segura, David Ming
Xu, Ruizhi
Zhou, Dongzhan
Zhang, Wenjie
Hoex, Bram
Schwaller, Philippe
author_facet Bran, Andres M
Xie, Tong
Pranesh, Shai
Meng, Jeffrey
Nguyen, Xuan Vu
Goumaz, Jeremy
Segura, David Ming
Xu, Ruizhi
Zhou, Dongzhan
Zhang, Wenjie
Hoex, Bram
Schwaller, Philippe
contents Large Language Models can develop reasoning capabilities through online fine-tuning with rule-based rewards. However, recent studies reveal a critical constraint: reinforcement learning succeeds only when the base model already assigns non-negligible probability to correct answers -- a property we term 'latent solvability'. This work investigates the emergence of chemical reasoning capabilities and what these prerequisites mean for chemistry. We identify two necessary conditions for RL-based chemical reasoning: 1) Symbolic competence, and 2) Latent chemical knowledge. We propose mid-stage scientific training (MiST): a set of mid-stage training techniques to satisfy these, including data-mixing with SMILES/CIF-aware pre-processing, continued pre-training on 2.9B tokens, and supervised fine-tuning on 1B tokens. These steps raise the latent-solvability score on 3B and 7B models by up to 1.8x, and enable RL to lift top-1 accuracy from 10.9 to 63.9% on organic reaction naming, and from 40.6 to 67.4% on inorganic material generation. Similar results are observed for other challenging chemical tasks, while producing interpretable reasoning traces. Our results define clear prerequisites for chemical reasoning training and highlight the broader role of mid-stage training in unlocking reasoning capabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2512_21231
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MiST: Understanding the Role of Mid-Stage Scientific Training in Developing Chemical Reasoning Models
Bran, Andres M
Xie, Tong
Pranesh, Shai
Meng, Jeffrey
Nguyen, Xuan Vu
Goumaz, Jeremy
Segura, David Ming
Xu, Ruizhi
Zhou, Dongzhan
Zhang, Wenjie
Hoex, Bram
Schwaller, Philippe
Machine Learning
Materials Science
Large Language Models can develop reasoning capabilities through online fine-tuning with rule-based rewards. However, recent studies reveal a critical constraint: reinforcement learning succeeds only when the base model already assigns non-negligible probability to correct answers -- a property we term 'latent solvability'. This work investigates the emergence of chemical reasoning capabilities and what these prerequisites mean for chemistry. We identify two necessary conditions for RL-based chemical reasoning: 1) Symbolic competence, and 2) Latent chemical knowledge. We propose mid-stage scientific training (MiST): a set of mid-stage training techniques to satisfy these, including data-mixing with SMILES/CIF-aware pre-processing, continued pre-training on 2.9B tokens, and supervised fine-tuning on 1B tokens. These steps raise the latent-solvability score on 3B and 7B models by up to 1.8x, and enable RL to lift top-1 accuracy from 10.9 to 63.9% on organic reaction naming, and from 40.6 to 67.4% on inorganic material generation. Similar results are observed for other challenging chemical tasks, while producing interpretable reasoning traces. Our results define clear prerequisites for chemical reasoning training and highlight the broader role of mid-stage training in unlocking reasoning capabilities.
title MiST: Understanding the Role of Mid-Stage Scientific Training in Developing Chemical Reasoning Models
topic Machine Learning
Materials Science
url https://arxiv.org/abs/2512.21231