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Main Authors: Zhao, Chongwen, Ke, Yutong, Huang, Kaizhu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.01631
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author Zhao, Chongwen
Ke, Yutong
Huang, Kaizhu
author_facet Zhao, Chongwen
Ke, Yutong
Huang, Kaizhu
contents Large Language Models (LLMs) are increasingly attracting attention in various applications. Nonetheless, there is a growing concern as some users attempt to exploit these models for malicious purposes, including the synthesis of controlled substances and the propagation of disinformation, a technique known as "Jailbreak." While some studies have achieved defenses against jailbreak attacks by modifying output distributions or detecting harmful content, the exact rationale still remains elusive. In this work, we present a novel neuron-level interpretability method that focuses on the role of safety-related knowledge neurons. Unlike existing approaches, our method projects the model's internal representation into a more consistent and interpretable vocabulary space. We then show that adjusting the activation of safety-related neurons can effectively control the model's behavior with a mean ASR higher than 97%. Building on this insight, we propose SafeTuning, a fine-tuning strategy that reinforces safety-critical neurons to improve model robustness against jailbreaks. SafeTuning consistently reduces attack success rates across multiple LLMs and outperforms all four baseline defenses. These findings offer a new perspective on understanding and defending against jailbreak attacks.
format Preprint
id arxiv_https___arxiv_org_abs_2509_01631
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unraveling LLM Jailbreaks Through Safety Knowledge Neurons
Zhao, Chongwen
Ke, Yutong
Huang, Kaizhu
Artificial Intelligence
Large Language Models (LLMs) are increasingly attracting attention in various applications. Nonetheless, there is a growing concern as some users attempt to exploit these models for malicious purposes, including the synthesis of controlled substances and the propagation of disinformation, a technique known as "Jailbreak." While some studies have achieved defenses against jailbreak attacks by modifying output distributions or detecting harmful content, the exact rationale still remains elusive. In this work, we present a novel neuron-level interpretability method that focuses on the role of safety-related knowledge neurons. Unlike existing approaches, our method projects the model's internal representation into a more consistent and interpretable vocabulary space. We then show that adjusting the activation of safety-related neurons can effectively control the model's behavior with a mean ASR higher than 97%. Building on this insight, we propose SafeTuning, a fine-tuning strategy that reinforces safety-critical neurons to improve model robustness against jailbreaks. SafeTuning consistently reduces attack success rates across multiple LLMs and outperforms all four baseline defenses. These findings offer a new perspective on understanding and defending against jailbreak attacks.
title Unraveling LLM Jailbreaks Through Safety Knowledge Neurons
topic Artificial Intelligence
url https://arxiv.org/abs/2509.01631