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Main Authors: Gong, Jiawei, Ma, Danqing, Bulanadi, Ralph, Moore, Robert, Vasudevan, Rama, Zhao, Lianfeng, Liu, Yongtao
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.17028
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author Gong, Jiawei
Ma, Danqing
Bulanadi, Ralph
Moore, Robert
Vasudevan, Rama
Zhao, Lianfeng
Liu, Yongtao
author_facet Gong, Jiawei
Ma, Danqing
Bulanadi, Ralph
Moore, Robert
Vasudevan, Rama
Zhao, Lianfeng
Liu, Yongtao
contents Microscopy combined with local spectroscopy is widely used to correlate nanoscale structure with functional properties in materials, but conventional measurements rely heavily on human-selected sampling locations and predefined targets, limiting dataset diversity and the potential for discovery. Here, we present a framework that integrates autonomous microscopy with a dual-novelty deep kernel learning (DN-DKL) for adaptive data acquisition and a dual variational autoencoder (VAE) for representation learning. DN-DKL actively guides the microscopy toward structurally and spectroscopically novel regions, enabling efficient collection of large spectral datasets. Dual-VAE embeds local structure and spectroscopic responses into a shared latent manifold that serves as a structure-property relationship map. We applied this framework for the investigation of halide perovskite films using conductive atomic force microscopy. The results reveal distinct hysteresis behaviors that are linked to specific nanoscale structural motifs, including grain boundary junction points that show hysteresis under different bias conditions and asymmetric grain boundaries that suppress charge transport. This framework establishes a general strategy that leverages the complementary strengths of self-driving microscopy, machine learning, and human expertise to accelerate scientific discovery in functional materials.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17028
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Accelerating Structure-Property Relationship Discovery with Multimodal Machine Learning and Self-Driving Microscopy
Gong, Jiawei
Ma, Danqing
Bulanadi, Ralph
Moore, Robert
Vasudevan, Rama
Zhao, Lianfeng
Liu, Yongtao
Materials Science
Instrumentation and Detectors
I.2.6; I.5.1; J.2
Microscopy combined with local spectroscopy is widely used to correlate nanoscale structure with functional properties in materials, but conventional measurements rely heavily on human-selected sampling locations and predefined targets, limiting dataset diversity and the potential for discovery. Here, we present a framework that integrates autonomous microscopy with a dual-novelty deep kernel learning (DN-DKL) for adaptive data acquisition and a dual variational autoencoder (VAE) for representation learning. DN-DKL actively guides the microscopy toward structurally and spectroscopically novel regions, enabling efficient collection of large spectral datasets. Dual-VAE embeds local structure and spectroscopic responses into a shared latent manifold that serves as a structure-property relationship map. We applied this framework for the investigation of halide perovskite films using conductive atomic force microscopy. The results reveal distinct hysteresis behaviors that are linked to specific nanoscale structural motifs, including grain boundary junction points that show hysteresis under different bias conditions and asymmetric grain boundaries that suppress charge transport. This framework establishes a general strategy that leverages the complementary strengths of self-driving microscopy, machine learning, and human expertise to accelerate scientific discovery in functional materials.
title Accelerating Structure-Property Relationship Discovery with Multimodal Machine Learning and Self-Driving Microscopy
topic Materials Science
Instrumentation and Detectors
I.2.6; I.5.1; J.2
url https://arxiv.org/abs/2603.17028