Self-driving laboratory for accelerated discovery of thin-film materials

MacLeod, Benjamin P.; Parlane, Fraser G. L.; Morrissey, Thomas D.; Häse, Florian; Roch, Loı̈c M.; Dettelbach, Kevan E.; Moreira, Raphaell; Yunker, Lars P. E.; Rooney, Michael B.; Deeth, Joseph R.; Lai, Veronica; Ng, Gordon J.; Situ, Henry; Zhang, R. H.; Elliott, Michael S.; Haley, Ted H.; Dvořák, Dalimil; Aspuru‐Guzik, Alán; Hein, Jason E.; Berlinguette, Curtis P.

doi:10.1126/sciadv.aaz8867

Cited by 368 publications

(307 citation statements)

References 38 publications

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“…4, including emerging reports from perovskite synthesis 78 and molecular materials for of organic photovoltaics 79 and organic hole transport materials. 80 Continuation of these concerted efforts to increase automation and develop tailored AI algorithms will enable the materials science community to realize a paradigm shi in scientic discovery where expert scientists can dedicate a substantially larger fraction of their time to performing the critical tasks of identifying important problems and communicating critical insights.…”

Section: Discussionmentioning

confidence: 99%

Progress and prospects for accelerating materials science with automated and autonomous workflows

2019

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Section: Discussionmentioning

confidence: 99%

Progress and prospects for accelerating materials science with automated and autonomous workflows

2019

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“…The automated combinatorial synthesis provides the opportunity of accelerating the production of materials with large compositional space. To date, several groups have demonstrated the applications of the automated experiment to materials discovery, including synthesis 38 and full device-preparation workflows 39 . Here, we show that a combination of laboratory automation and machine learning can be used for the rapid mapping of both the concentration-dependent physical properties and long-term stability in broad concentration spaces of hybrid organic-inorganic perovskites, demonstrating the presence of the regions with high stability.…”

Section: Discussionmentioning

confidence: 99%

Chemical Robotics Enabled Exploration of Stability and Photoluminescent Behavior in Multicomponent Hybrid Perovskites via Machine Learning

Higgins¹,

Valleti²,

Ziatdinov

et al. 2020

Preprint

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Hybrid organic-inorganic perovskites have attracted immense interest as a promising material for the next-generation solar cells; however, issues regarding long-term stability still require further study. Here, we develop automated experimental workflow based on combinatorial synthesis and rapid throughput characterization to explore long-term stability of these materials in ambient conditions, and apply it to four model perovskite systems: MAxFAyCs1-x-yPbBr3, MAxFAyCs1-x-yPbI3, (CsxFAyMA1-x-yPb(Brx+yI1-x-y)3) and (CsxMAyFA1-x-yPb(Ix+yBr1-x-y)3). We also develop a machine learning-based workflow to quantify the evolution of each system as a function of composition based on overall changes in photoluminescence spectra, as well as specific peak positions and intensities. We find the stability dependence on composition to be extremely non-uniform within the composition space, suggesting the presence of potential preferential compositional regions. This proposed workflow is universal and can be applied to other perovskite systems and solution-processable materials. Furthermore, incorporation of experimental optimization methods, e.g., those based on Gaussian Processes, will enable the transition from combinatorial synthesis to guide materials research and optimization.

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“…To illustrate the applicability of our method to thin film optimization, we used DeepThin to resolve a 2-dimensional filmmorphology response surface in a set of experiments where both film composition and processing were varied. Following our previous work 30 , thin films of spiro-OMeTAD doped with varying amounts of FK102 Co(III) TFSI salt and annealed for varying durations were prepared and then imaged using a robotic platform (see "Methods" section). These experiments provided an array of images exhibiting morphological trends as a function of both film composition and processing.…”

Section: Resolution Of a Two-dimensional Film-morphology Response Surmentioning

confidence: 99%

“…These films were deposited by spincoating, annealed, and imaged by a flexible robotic platform equipped with a darkfield photography system (see "Methods" section, ref. 30 ). The images in this darkfield dataset were labeled with respect to the extent of dewetting and of cracking by materials scientists with expertise in thin-film materials research (see "Methods" section).…”

Section: Introductionmentioning

confidence: 99%

Quantifying defects in thin films using machine vision

et al. 2020

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The sensitivity of thin-film materials and devices to defects motivates extensive research into the optimization of film morphology. This research could be accelerated by automated experiments that characterize the response of film morphology to synthesis conditions. Optical imaging can resolve morphological defects in thin films and is readily integrated into automated experiments but the large volumes of images produced by such systems require automated analysis. Existing approaches to automatically analyzing film morphologies in optical images require application-specific customization by software experts and are not robust to changes in image content or imaging conditions. Here, we present a versatile convolutional neural network (CNN) for thin-film image analysis which can identify and quantify the extent of a variety of defects and is applicable to multiple materials and imaging conditions. This CNN is readily adapted to new thin-film image analysis tasks and will facilitate the use of imaging in automated thin-film research systems.

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Self-driving laboratory for accelerated discovery of thin-film materials

Cited by 368 publications

References 38 publications

Progress and prospects for accelerating materials science with automated and autonomous workflows

Progress and prospects for accelerating materials science with automated and autonomous workflows

Chemical Robotics Enabled Exploration of Stability and Photoluminescent Behavior in Multicomponent Hybrid Perovskites via Machine Learning

Quantifying defects in thin films using machine vision

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