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Reimagining the Philosophy of Experimentation in Chemistry Education: Embracing AI as a Tool for Scientific Inquiry

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Abstract

The integration of artificial intelligence (AI) into scientific disciplines is revolutionizing both research methodologies and educational paradigms. AI tools are reshaping traditional experimental approaches, challenging established notions of scientific discovery, and creating novel opportunities for enhanced learning experiences. This shift necessitates a thoughtful reimagining of the approach to the philosophy of experimentation, challenging long-held epistemological, methodological, and ethical frameworks, and balancing the power of AI with the irreplaceable aspects of human-driven scientific exploration. This article examines the transformative impact of AI on the philosophy of experimentation in the context of chemistry education. AI-driven methodologies in chemistry laboratory classes are fostering a deeper understanding of chemical phenomena while simultaneously raising essential questions about the role of human intuition and creativity in scientific inquiry. Ethical considerations and potential pitfalls of over-reliance on AI in chemical experimentation must also be carefully addressed, specifically how AI automates routine tasks, fundamentally altering how experiments are conceptualized and conducted in chemistry education. A framework for integrating AI into chemistry education that maximizes its benefits while preserving the essential elements of scientific reasoning and discovery is crucial. This work contributes to the ongoing dialogue on the future of chemistry education, offering insights into how AI can be integrated into the experimental philosophy to maximize its benefits while preserving the essential aspects of scientific reasoning and discovery.

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  • Chemistry Education
  • Chemistry Policy
  • Educational Philosophy
  • Experimental Philosophy
  • Philosophy of Artificial Intelligence
  • Philosophy of Chemistry

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This research did not involve the generation of new datasets.

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Acknowledgements

The authors gratefully acknowledge the support and encouragement of the Physical Sciences and Mathematics Department, School of Science and Technology, Centro Escolar University, Manila (RLR), and the Mathematics and Sciences cluster of the General Education Department within the College of Education, Arts, and Sciences at the National University, Manila, Philippines (JDR).

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Authors and Affiliations

  1. Physical Sciences and Mathematics, School of Science and Technology, Centro Escolar University, 9 Mendiola Street, San Miguel, City of Manila, 1008, Philippines

    Ronald L. Reyes

  2. Science and Mathematics, Institute of General Education, National University, 551 F. Jhocson Street, Sampaloc, City of Manila, 1008, Philippines

    Jennifer D. Regala

Contributions

Ronald L. Reyes: conceptualization, methodology, analysis of available data and literature, data curation, writing—original draft, writing—review and edit, visualization—preparation of figures, supervision. Jennifer D. Regala: methodology, analysis of available data and literature, data curation, writing—review and edit.

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Correspondence to Ronald L. Reyes.

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Reyes, R.L., Regala, J.D. Reimagining the Philosophy of Experimentation in Chemistry Education: Embracing AI as a Tool for Scientific Inquiry. Sci & Educ (2025). https://doi.org/10.1007/s11191-025-00667-8

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  • DOI https://doi.org/10.1007/s11191-025-00667-8

Keywords

  • Artificial intelligence
  • Chemistry education
  • Experimental philosophy
  • Virtual reality
  • STEM pedagogy

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