Composition Gradient High-Throughput Polymer Libraries Enabled by Passive Mixing and Elevated Temperature Operability

Liu, Aaron L.; Dogan-Guner, Ezgi M.; McBride, Michael; Venkatesh, R.; González, Miguel A.; Reichmanis, Elsa; Grover, Martha A.; Meredith, J. Carson

doi:10.1021/acs.chemmater.2c01500

Cited by 6 publications

(4 citation statements)

References 54 publications

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“…To tackle the labor-intensiveness of material discovery and device optimization process, high-throughput experimentation approaches have been developed . With the advantage of solution processing that enables parametric gradients in several processing conditions, researchers could leverage parameters such as thickness, , precursor solution formulation, ,− and temperature , to optimize the device performance. Researchers have also implemented self-driven laboratories based on autonomous robotic experimental platform and combined with machine learning (ML) or artificial intelligence (AI) to further minimize human resources and increase the data yield and reproducibility.…”

Section: Discussionmentioning

confidence: 99%

From Solution to Thin Film: Molecular Assembly of π-Conjugated Systems and Impact on (Opto)electronic Properties

Khasbaatar,

Xu,

Lee

et al. 2023

Chem. Rev.

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The assembly of conjugated organic molecules from solution to solid-state plays a critical role in determining the thin film morphology and optoelectronic properties of solution-processed organic electronics and photovoltaics. During evaporative solution processing, π-conjugated systems can assemble via various forms of intermolecular interactions, forming distinct aggregate structures that can drastically tune the charge transport landscape in the solid-state. In blend systems composed of donor polymer and acceptor molecules, assembly of neat materials couples with phase separation and crystallization processes, leading to complex phase transition pathways which govern the blend film morphology. In this review, we provide an in-depth review of molecular assembly processes in neat conjugated polymers and nonfullerene small molecule acceptors and discuss their impact on the thin film morphology and optoelectronic properties. We then shift our focus to blend systems relevant to organic solar cells and discuss the fundamentals of phase transition and highlight how the assembly of neat materials and processing conditions can affect blend morphology and device performance.

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Section: Discussionmentioning

confidence: 99%

From Solution to Thin Film: Molecular Assembly of π-Conjugated Systems and Impact on (Opto)electronic Properties

Khasbaatar,

Xu,

Lee

et al. 2023

Chem. Rev.

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“…As examples, machine learning techniques have been employed in composition searches, [9][10][11][12][13] crystal phase and microstructure classifications 14,15 and physical property predictions. 16,17 Within the field of polymer chemistry, informatics is increasingly being applied to the design of polymers [18][19][20][21] and the prediction of properties [22][23][24] based on the use of molecular descriptors. Bayesian optimization (BO), in particular, has emerged as a powerful tool in many scientific disciplines, including materials science.…”

Section: Introductionmentioning

confidence: 99%

Bayesian optimization of radical polymerization reactions in a flow synthesis system

Takasuka,

Ito,

Oikawa

et al. 2024

Preprint

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The proportional amounts of monomers within a copolymer will greatly affect the properties of the material. However, as known as composition drift, the monomer ratio in a copolymer can deviate from the value expected from the raw material ratio due to differences in monomer reactivity. Hence, it is therefore necessary to optimize the polymerization process on the basis that this inevitable composition drift will take place. In the present study, styrene-methyl methacrylate copolymers were generated using a flow synthesis system and the processing variables were tuned employing Bayesian optimization (BO) to obtain a target composition. Initial trials employed BO to produce four candidate points per cycle, completing the optimization within five cycles, and the solvent-to-monomer ratio was identified as the most important variable. Subsequent BO tests employed 40 points per cycle and established that multiple sets of processing conditions could provide the desired composition, but with variations in the physical properties of the copolymers. The role of each variable in the radical polymerization reaction was elucidated by assessing the extensive array of processing conditions while evaluating several broad trends. The proposed model confirms that specific monomer proportions can be produced in a copolymer using machine learning while investigating the reaction mechanism. In the future, the use of multi-objective BO to fine-tune the processing conditions is expected to allow optimization of the copolymer composition together with adjustment of physical properties.

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“…But the paradigm of rational design and discovery has increasingly been supplanted by theory-driven exploration and combinatorial, highthroughput experimentation. [8][9][10] Recently, artificial intelligence (AI)-guided closed-loop platforms, where predictions, experiments, and analysis are automated and connected in a positive feedback loop, have shown great potential to accelerate scientific discovery in intractably large search spaces. [11][12][13][14][15][16][17][18][19][20][21][22][23][24] Despite these recent successes, it is not yet possible to broadly leverage such a paradigm to drive knowledge-based discovery of molecular functions.…”

Section: Introductionmentioning

confidence: 99%

Closed-Loop Transfer Enables AI to Yield Chemical Knowledge

Angello,

Friday,

Hwang

et al. 2023

Preprint

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AI-guided closed-loop experimentation has recently emerged as a promising method to optimize objective functions,1,2 but the substantial potential of this traditionally black-box approach to reveal new scientific knowledge has remained largely untapped. Here, we report a new AI-guided approach, dubbed Closed-Loop Transfer (CLT), that integrates closed-loop experiments with physics-based feature selection and supervised learning to yield new scientific knowledge in parallel with optimization of objective functions. CLT surprisingly revealed that high-energy regions of the triplet state manifold are paramount in dictating molecular photostability in solution across a diverse chemical library of light-harvesting donor-bridge-acceptor oligomers. Remarkably, this insight emerged after automated modular synthesis and experimental characterization of only ~1.5% of the theoretical chemical space. Supervised learning models considering millions of combinations of 100+ physics-based descriptors further showed that high energy triplet states most strongly correlate with photostability, while excluding more commonly considered predictors such as the lowest energy triplet state. The physics-informed model for photostability was even further confirmed and then strengthened using an explicit experimental test set, validating the substantial power of the CLT method. Broadly, these findings show that interfacing physics-based modeling with closed-loop discovery campaigns unimpeded by synthesis bottlenecks can rapidly illuminate fundamental chemical insights and guide more rational pursuit of frontier molecular functions.

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Composition Gradient High-Throughput Polymer Libraries Enabled by Passive Mixing and Elevated Temperature Operability

Cited by 6 publications

References 54 publications

From Solution to Thin Film: Molecular Assembly of π-Conjugated Systems and Impact on (Opto)electronic Properties

From Solution to Thin Film: Molecular Assembly of π-Conjugated Systems and Impact on (Opto)electronic Properties

Bayesian optimization of radical polymerization reactions in a flow synthesis system

Closed-Loop Transfer Enables AI to Yield Chemical Knowledge

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