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Main Authors: Han, Xiaoxue, Zhang, Libo, Zhu, Zining, Ning, Yue
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.11986
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author Han, Xiaoxue
Zhang, Libo
Zhu, Zining
Ning, Yue
author_facet Han, Xiaoxue
Zhang, Libo
Zhu, Zining
Ning, Yue
contents We introduce Graph Concept Bottleneck (GCB) as a new paradigm for self-explainable text-attributed graph learning. GCB maps graphs into a subspace, concept bottleneck, where each concept is a meaningful phrase, and predictions are made based on the activation of these concepts. Unlike existing interpretable graph learning methods that primarily rely on subgraphs as explanations, the concept bottleneck provides a new form of interpretation. To refine the concept space, we apply the information bottleneck principle to focus on the most relevant concepts. This not only yields more concise and faithful explanations but also explicitly guides the model to "think" toward the correct decision. We empirically show that GCB achieves intrinsic interpretability with accuracy on par with black-box Graph Neural Networks. Moreover, it delivers better performance under distribution shifts and data perturbations, showing improved robustness and generalizability, benefitting from concept-guided prediction.
format Preprint
id arxiv_https___arxiv_org_abs_2604_11986
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Exploring Concept Subspace for Self-explainable Text-Attributed Graph Learning
Han, Xiaoxue
Zhang, Libo
Zhu, Zining
Ning, Yue
Machine Learning
We introduce Graph Concept Bottleneck (GCB) as a new paradigm for self-explainable text-attributed graph learning. GCB maps graphs into a subspace, concept bottleneck, where each concept is a meaningful phrase, and predictions are made based on the activation of these concepts. Unlike existing interpretable graph learning methods that primarily rely on subgraphs as explanations, the concept bottleneck provides a new form of interpretation. To refine the concept space, we apply the information bottleneck principle to focus on the most relevant concepts. This not only yields more concise and faithful explanations but also explicitly guides the model to "think" toward the correct decision. We empirically show that GCB achieves intrinsic interpretability with accuracy on par with black-box Graph Neural Networks. Moreover, it delivers better performance under distribution shifts and data perturbations, showing improved robustness and generalizability, benefitting from concept-guided prediction.
title Exploring Concept Subspace for Self-explainable Text-Attributed Graph Learning
topic Machine Learning
url https://arxiv.org/abs/2604.11986