Text Mining the Literature to Inform Experiments and Rationalize Impurity Phase Formation for BiFeO

Overview

Journal Chem Mater

Date 2024 Jan 29

PMID 38282687

Authors

Kevin Cruse

Viktoriia Baibakova

Maged Abdelsamie

Kootak Hong

Christopher J Bartel

Amalie Trewartha

Anubhav Jain

Carolin M Sutter-Fella

Gerbrand Ceder

Affiliations

Soon will be listed here.

Abstract

We used data-driven methods to understand the formation of impurity phases in BiFeO thin-film synthesis through the sol-gel technique. Using a high-quality dataset of 331 synthesis procedures and outcomes extracted manually from 177 scientific articles, we trained decision tree models that reinforce important experimental heuristics for the avoidance of phase impurities but ultimately show limited predictive capability. We find that several important synthesis features, identified by our model, are often not reported in the literature. To test our ability to correctly impute missing synthesis parameters, we attempted to reproduce nine syntheses from the literature with varying degrees of "missingness". We demonstrate how a text-mined dataset can be made useful by informing new controlled experiments and forming a better understanding for impurity phase formation in this complex oxide system.

Citing Articles

Control of Crystallization Pathways in the BiFeO-BiFeO System.

Kirsch A, Strapasson G, Lefeld N, Gogolin M, Videbaek M, Banerjee S Chem Mater. 2025; 37(1):338-348.

PMID: 39830220 PMC: 11736678. DOI: 10.1021/acs.chemmater.4c02656.

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