Beyond Optimization: Exploring Novelty Discovery in Autonomous Experiments

Ralph Bulanadi; Jawad Chowdhury; Hiroshi Funakubo; Maxim Ziatdinov; Rama Vasudevan; Arpan Biswas; Yongtao Liu

doi:10.1021/acsnanoscienceau.5c00106

Beyond Optimization: Exploring Novelty Discovery in Autonomous Experiments

Ralph Bulanadi
, Jawad Chowdhury
, Hiroshi Funakubo
, Maxim Ziatdinov
, Rama Vasudevan
, Arpan Biswas
, Yongtao Liu

Data Nanoanalytics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Autonomous experiments (AEs) are transforming how scientific research is conducted by integrating artificial intelligence with automated experimental platforms. Current AEs primarily focus on the optimization of a predefined target; while accelerating this goal, such an approach limits the discovery of unexpected or unknown physical phenomena. Here, we introduce a novel framework, INS²ANE (Integrated Novelty Score–Strategic Autonomous Non-Smooth Exploration), to enhance the discovery of novel phenomena in autonomous microscopy experimentation. Our method integrates two key components: (1) a novelty scoring system that evaluates the uniqueness of experimental results and (2) a strategic sampling mechanism that promotes exploration of under-sampled regions even if they appear less promising by conventional criteria. We validate this approach on a preacquired data set with a known ground truth comprising of image–spectral pairs. We further implement the process on autonomous scanning probe microscopy experiments. INS²ANE significantly increases the diversity of explored phenomena in comparison to conventional optimization routines, enhancing the likelihood of discovering previously unobserved phenomena. These results demonstrate the potential for autonomous microscopy experiments to enhance the scientific discovery by navigating complex experimental spaces to uncover novel phenomena.

Original language	English
Pages (from-to)	86-94
Number of pages	9
Journal	ACS Nanoscience Au
Volume	6
Issue number	1
DOIs	https://doi.org/10.1021/acsnanoscienceau.5c00106
State	Published - Feb 18 2026

Funding

This research and workflow development was sponsored by the INTERSECT Initiative as part of the Laboratory Directed Research and Development Program of Oak Ridge National Laboratory, managed by UT-Battelle, LLC for the US Department of Energy under contract DE-AC05-00OR22725. Piezoresponse force microscopy was performed at and supported by the Center for Nanophase Materials Sciences (CNMS), which is a US Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory. Development of the SANE algorithm acknowledges the use of facilities and instrumentation at the UT Knoxville Institute for Advanced Materials and Manufacturing (IAMM) and the Shull Wollan Center (SWC), supported in part by the National Science Foundation Materials Research Science and Engineering Center program through the UT Knoxville Center for Advanced Materials and Manufacturing (DMR-2309083). The authors acknowledge Ganesh Narasimha for valuable discussions and insightful suggestions. H.F. was supported by MEXT Program: Data Creation and Utilization Type Material Research and Development Project (No. JPMXP1122683430) and MEXT Initiative to Establish Next-generation Novel Integrated Circuits Centers (XNICS) (JPJ011438), and the Japan Science and Technology Agency (JST) as part of Adopting Sustainable Partnerships for Innovative Research Ecosystem (ASPIRE), Grant Number JPMJAP2312.

Keywords

artificial intelligence
autonomous experiments
ferroelectrics
machine learning
novelty
piezoresponse force microscopy

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10.1021/acsnanoscienceau.5c00106

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title = "Beyond Optimization: Exploring Novelty Discovery in Autonomous Experiments",

abstract = "Autonomous experiments (AEs) are transforming how scientific research is conducted by integrating artificial intelligence with automated experimental platforms. Current AEs primarily focus on the optimization of a predefined target; while accelerating this goal, such an approach limits the discovery of unexpected or unknown physical phenomena. Here, we introduce a novel framework, INS2ANE (Integrated Novelty Score–Strategic Autonomous Non-Smooth Exploration), to enhance the discovery of novel phenomena in autonomous microscopy experimentation. Our method integrates two key components: (1) a novelty scoring system that evaluates the uniqueness of experimental results and (2) a strategic sampling mechanism that promotes exploration of under-sampled regions even if they appear less promising by conventional criteria. We validate this approach on a preacquired data set with a known ground truth comprising of image–spectral pairs. We further implement the process on autonomous scanning probe microscopy experiments. INS2ANE significantly increases the diversity of explored phenomena in comparison to conventional optimization routines, enhancing the likelihood of discovering previously unobserved phenomena. These results demonstrate the potential for autonomous microscopy experiments to enhance the scientific discovery by navigating complex experimental spaces to uncover novel phenomena.",

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author = "Ralph Bulanadi and Jawad Chowdhury and Hiroshi Funakubo and Maxim Ziatdinov and Rama Vasudevan and Arpan Biswas and Yongtao Liu",

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Beyond Optimization: Exploring Novelty Discovery in Autonomous Experiments

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