Uncertainty-Informed Screening for Safer Solvents Used in the Synthesis of Perovskite via Language Models

The challenge of accurately predicting toxicity of industrial solvents used in perovskite synthesis is a necessary undertaking but is limited by a lack of a targeted and structured toxicity data. This paper presents a novel framework that combines an automated data extraction using language models,...

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Bibliographic Details
Published in:arXiv.org 2024-09
Main Authors: Mukherjee, Arpan, Giri, Deepesh, Rajan, Krishna
Format: Article
Language:English
Subjects:
Classification
Entropy (Information theory)
Hazard assessment
Hazard identification
Large language models
Machine learning
Perovskites
Prediction models
Predictions
Solvents
Synthesis
Toxic hazards
Toxicity
Uncertainty
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Summary:The challenge of accurately predicting toxicity of industrial solvents used in perovskite synthesis is a necessary undertaking but is limited by a lack of a targeted and structured toxicity data. This paper presents a novel framework that combines an automated data extraction using language models, and an uncertainty-informed prediction model to fill data gaps and improve prediction confidence. First, we have utilized and compared two approaches to automatically extract relevant data from a corpus of scientific literature on solvents used in perovskite synthesis: smaller bidirectional language models like BERT and ELMo are used for their repeatability and deterministic outputs, while autoregressive large language model (LLM) such as GPT-3.5 is used to leverage its larger training corpus and better response generation. Our novel 'prompting and verification' technique integrated with an LLM aims at targeted extraction and refinement, thereby reducing hallucination and improving the quality of the extracted data using the LLM. Next, the extracted data is fed into our pre-trained multi-task binary classification deep learning to predict the ED nature of extracted solvents. We have used a Shannon entropy-based uncertainty quantification utilizing the class probabilities obtained from the classification model to quantify uncertainty and identify data gaps in our predictions. This approach leads to the curation of a structured dataset for solvents used in perovskite synthesis and their uncertainty-informed virtual toxicity assessment. Additionally, chord diagrams have been used to visualize solvent interactions and prioritize those with potential hazards, revealing that 70% of the solvent interactions were primarily associated with two specific perovskites.
ISSN:2331-8422