Cross-Modal Characterization of Thin Film MoS$_2$ Using Generative Models
This addresses the challenge of reducing expert time and resources in materials science by enabling cross-modal characterization, though it appears incremental as it builds on existing ML approaches in the field.
The study tackled the problem of accelerating materials characterization by using machine learning to project quantitative metrics from microscopy (AFM) using spectroscopy data (Raman), and trained generative models to generate full spectral features from each other and AFM images for thin film MoS2, with promising results that provide a foundational guide for efficient and cost-effective discovery.
The growth and characterization of materials using empirical optimization typically requires a significant amount of expert time, experience, and resources. Several complementary characterization methods are routinely performed to determine the quality and properties of a grown sample. Machine learning (ML) can support the conventional approaches by using historical data to guide and provide speed and efficiency to the growth and characterization of materials. Specifically, ML can provide quantitative information from characterization data that is typically obtained from a different modality. In this study, we have investigated the feasibility of projecting the quantitative metric from microscopy measurements, such as atomic force microscopy (AFM), using data obtained from spectroscopy measurements, like Raman spectroscopy. Generative models were also trained to generate the full and specific features of the Raman and photoluminescence spectra from each other and the AFM images of the thin film MoS$_2$. The results are promising and have provided a foundational guide for the use of ML for the cross-modal characterization of materials for their accelerated, efficient, and cost-effective discovery.