AI Article Synopsis
- Materials scientists face challenges in effectively using unstructured data to enhance structured datasets, especially in applied fields like materials science.
- This study introduces a new natural language processing task named structured information inference (SII) that aims to convert literature-based information into structured data for better usability.
- By fine-tuning the LLaMA model, the researchers achieved an impressive F1 score of 87.14%, successfully updating a perovskite solar cell dataset and demonstrating that large language models can compete with traditional methods in predicting material performance without the need for extensive feature selection.
Article Abstract
Materials scientists usually collect experimental data to summarize experiences and predict improved materials. However, a crucial issue is how to proficiently utilize unstructured data to update existing structured data, particularly in applied disciplines. This study introduces a new natural language processing (NLP) task called structured information inference (SII) to address this problem. We propose an end-to-end approach to summarize and organize the multi-layered device-level information from the literature into structured data. After comparing different methods, we fine-tuned LLaMA with an F1 score of 87.14% to update an existing perovskite solar cell dataset with articles published since its release, allowing its direct use in subsequent data analysis. Using structured information, we developed regression tasks to predict the electrical performance of solar cells. Our results demonstrate comparable performance to traditional machine-learning methods without feature selection and highlight the potential of large language models for scientific knowledge acquisition and material development.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11117053 | PMC |
| http://dx.doi.org/10.1016/j.patter.2024.100955 | DOI Listing |
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