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Main Authors: Su, Chang, Hao, Zhongkai, Zhang, Zhizhou, Xia, Zeyu, Wu, Youjia, Su, Hang, Zhu, Jun
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07642
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author Su, Chang
Hao, Zhongkai
Zhang, Zhizhou
Xia, Zeyu
Wu, Youjia
Su, Hang
Zhu, Jun
author_facet Su, Chang
Hao, Zhongkai
Zhang, Zhizhou
Xia, Zeyu
Wu, Youjia
Su, Hang
Zhu, Jun
contents Large language models (LLMs) with reasoning abilities have demonstrated growing promise for tackling complex scientific problems. Yet such tasks are inherently domain-specific, unbounded and open-ended, demanding exploration across vast and flexible solution spaces. Existing approaches, whether purely learning-based or reliant on carefully designed workflows, often suffer from limited exploration efficiency and poor generalization. To overcome these challenges, we present HELIX -- a Hierarchical Evolutionary reinforcement Learning framework with In-context eXperiences. HELIX introduces two key novelties: (i) a diverse yet high-quality pool of candidate solutions that broadens exploration through in-context learning, and (ii) reinforcement learning for iterative policy refinement that progressively elevates solution quality. This synergy enables the discovery of more advanced solutions. On the circle packing task, HELIX achieves state-of-the-art result with a sum of radii of 2.63598308 using only a 14B model. Across standard machine learning benchmarks, HELIX further surpasses GPT-4o with a carefully engineered pipeline, delivering an average F1 improvement of 5.95 points on the Adult and Bank Marketing datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07642
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Helix: Evolutionary Reinforcement Learning for Open-Ended Scientific Problem Solving
Su, Chang
Hao, Zhongkai
Zhang, Zhizhou
Xia, Zeyu
Wu, Youjia
Su, Hang
Zhu, Jun
Machine Learning
Large language models (LLMs) with reasoning abilities have demonstrated growing promise for tackling complex scientific problems. Yet such tasks are inherently domain-specific, unbounded and open-ended, demanding exploration across vast and flexible solution spaces. Existing approaches, whether purely learning-based or reliant on carefully designed workflows, often suffer from limited exploration efficiency and poor generalization. To overcome these challenges, we present HELIX -- a Hierarchical Evolutionary reinforcement Learning framework with In-context eXperiences. HELIX introduces two key novelties: (i) a diverse yet high-quality pool of candidate solutions that broadens exploration through in-context learning, and (ii) reinforcement learning for iterative policy refinement that progressively elevates solution quality. This synergy enables the discovery of more advanced solutions. On the circle packing task, HELIX achieves state-of-the-art result with a sum of radii of 2.63598308 using only a 14B model. Across standard machine learning benchmarks, HELIX further surpasses GPT-4o with a carefully engineered pipeline, delivering an average F1 improvement of 5.95 points on the Adult and Bank Marketing datasets.
title Helix: Evolutionary Reinforcement Learning for Open-Ended Scientific Problem Solving
topic Machine Learning
url https://arxiv.org/abs/2603.07642