Self‐Driven Multistep Quantum Dot Synthesis Enabled by Autonomous Robotic Experimentation in Flow

Abdel‐Latif, Kameel; Epps, Robert W.; Bateni, Fazel; Han, Suyong; Reyes, Kristofer G.; Abolhasani, Milad

doi:10.1002/aisy.202000245

Cited by 61 publications

(47 citation statements)

References 65 publications

(108 reference statements)

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“…The use of PFO serves two purposes: i) it is used as a carrier phase to segment the reactive phase and induce an axisymmetric swirling pattern within the formed droplets to enhance mixing, and ii) it preferentially wets the PFA inner wall and forms a lubrication film to isolate the reactive droplets and prevent fouling. [4,[40][41][42] The Cs precursor stream is mixed with an octadecene (ODE)/oleic acid (OA) solvent stream at the room temperature, using a T-junction (IDEX Health and Sciences), before entering the flow segmentation module to achieve the desired Cs concentration (Figure 2A). The segmentation module is a custom-machined four-way junction (polyether ether ketone), specifically designed to achieve reliable and uniform flow segmentation with two reactive streams and a carrier fluid.…”

Section: Resultsmentioning

confidence: 99%

“…The flow cell is a machined aluminum block with three optical fiber (Ocean Insight, 600 µm diameter) ports and a fluorinated ethylene propylene tubing (OD: 1/16 in., ID: 0.03 in.). [40] The flow cell allows for real-time spectral characterization of the inflow synthesized CsPbI 3 NCs through UV-vis absorption and photoluminescence (PL) spectroscopy (Figure 2A). The optical fibers are connected to a broadband light source (Ocean Insight, DH-2000-BAL) for UV-vis absorption spectroscopy, a 450 nm light emitting diode (Thorlabs) as the PL excitation source, and a miniature fiber-coupled spectrometer (Ocean Insight, HDX).…”

Section: Resultsmentioning

confidence: 99%

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CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

Antami

Bateni

Ramezani

et al. 2021

Adv Funct Materials

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Despite the groundbreaking advancements in the synthesis of inorganic lead halide perovskite (LHP) nanocrystals (NCs), stimulated from their intriguing size-, composition-, and morphology-dependent optical and optoelectronic properties, their formation mechanism through the hot-injection (HI) synthetic route is not well-understood. In this work, for the first time, in-flow HI synthesis of cesium lead iodide (CsPbI 3 ) NCs is introduced and a comprehensive understanding of the interdependent competing reaction parameters controlling the NC morphology (nanocube vs nanoplatelet) and properties is provided. Utilizing the developed flow synthesis strategy, a change in the CsPbI 3 NC formation mechanism at temperatures higher than 150 °C, resulting in different CsPbI 3 morphologies is revealed. Through comparison of the flow-versus flask-based synthesis, deficiencies of batch reactors in reproducible and scalable synthesis of CsPbI 3 NCs with fast formation kinetics are demonstrated. The developed modular flow chemistry route provides a new frontier for high-temperature studies of solution-processed LHP NCs and enables their consistent and reliable continuous nanomanufacturing for next-generation energy technologies.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

Antami

Bateni

Ramezani

et al. 2021

Adv Funct Materials

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“…However, there are examples of successful SDL projects and their applications for the discovery of new materials, including clean energy technologies [ 19 ], organic photovoltaics [ 67 ], discovery of thin film materials [ 17 ], autonomous synthesis of carbon nanotubes [ 68 ], and self-driving ”Artificial Chemist” [ 18 ] for producing inorganic perovskite and inorganic lead halide perovskite quantum dots [ 69 ]. It is worth noting that the functionality of each instance of SDL is limited and depends greatly on certain aims and areas of research and application.…”

Section: Data-centric Research Strategymentioning

confidence: 99%

“…In principle, operations that are simple, even for an inexperienced person, such as pressing a powder sample into a cell and connecting the necessary connectors in an X-ray absorption spectrometer, can cause extreme difficulties and be a serious obstacle for an automatic robotic platform. Due to this, the flow chemistry approach has more capabilities to be fully automated currently, for example [ 62 , 69 , 71 ]. However, regardless of whether the process is available or unavailable, the ability to obtain automated and autonomous chemistry synthesis processes followed by nanomaterial characterization the automated workflow is the main provider of new scientific research data at SDL architecture.…”

Section: Data-centric Sdl Architecturementioning

confidence: 99%

Data-Centric Architecture for Self-Driving Laboratories with Autonomous Discovery of New Nanomaterials

et al. 2021

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Artificial intelligence (AI) approaches continue to spread in almost every research and technology branch. However, a simple adaptation of AI methods and algorithms successfully exploited in one area to another field may face unexpected problems. Accelerating the discovery of new functional materials in chemical self-driving laboratories has an essential dependence on previous experimenters’ experience. Self-driving laboratories help automate and intellectualize processes involved in discovering nanomaterials with required parameters that are difficult to transfer to AI-driven systems straightforwardly. It is not easy to find a suitable design method for self-driving laboratory implementation. In this case, the most appropriate way to implement is by creating and customizing a specific adaptive digital-centric automated laboratory with a data fusion approach that can reproduce a real experimenter’s behavior. This paper analyzes the workflow of autonomous experimentation in the self-driving laboratory and distinguishes the core structure of such a laboratory, including sensing technologies. We propose a novel data-centric research strategy and multilevel data flow architecture for self-driving laboratories with the autonomous discovery of new functional nanomaterials.

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“…The ML algorithms may be thought of as an adaptive form of experimental design, which allows one to efficiently identify reaction conditions that yield NPs with desired properties. Self-driving MF platforms integrated with ML have been used for the synthesis of metal chalcogenide quantum dots, [32] perovskite, [33][34][35] and metal NPs. [36] The ML algorithms searched within a predefined parameter space when targeting for certain characteristics in the photoluminescence or absorption spectra of the NPs such as emission and absorption wavelength, as well as linewidth.…”

Section: Introductionmentioning

confidence: 99%

Self‐Driving Platform for Metal Nanoparticle Synthesis: Combining Microfluidics and Machine Learning

Tao

Kheiri

et al. 2021

Adv Funct Materials

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Many applications of inorganic nanoparticles (NPs), including photocatalysis, photovoltaics, chemical and biochemical sensing, and theranostics, are governed by NP optical properties. Exploration and identification of reaction conditions for the synthesis of NPs with targeted spectroscopic characteristics is a time-, labor-, and resource-intensive task, as it involves the optimization of multiple interdependent reaction conditions. Integration of machine learning (ML) and microfluidics (MF) offers accelerated identification and optimization of reaction conditions for NP synthesis. Here, an autonomous ML-driven, oscillatory MF platform for the synthesis of NPs is reported. The platform utilized multiple recipes and reaction times for the synthesis of NPs with different dimensions, conducted spectroscopic NP characterization, and employed ML approaches to analyze multiple yet prioritized spectroscopic NP characteristics, and identified reaction conditions for the synthesis of NPs with targeted optical properties. The platform is also used to develop an understanding of the relationship between reaction conditions and NP properties. This study shows the strong potential of ML-driven oscillatory MF platforms in materials science and paves the way for automated NP development.

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Self‐Driven Multistep Quantum Dot Synthesis Enabled by Autonomous Robotic Experimentation in Flow

Cited by 61 publications

References 65 publications

CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

Data-Centric Architecture for Self-Driving Laboratories with Autonomous Discovery of New Nanomaterials

Self‐Driving Platform for Metal Nanoparticle Synthesis: Combining Microfluidics and Machine Learning

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Self‐Driven Multistep Quantum Dot Synthesis Enabled by Autonomous Robotic Experimentation in Flow

Cited by 61 publications

References 65 publications

CsPbI3 Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

CsPbI3 Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

Data-Centric Architecture for Self-Driving Laboratories with Autonomous Discovery of New Nanomaterials

Self‐Driving Platform for Metal Nanoparticle Synthesis: Combining Microfluidics and Machine Learning

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Product

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CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing

CsPbI₃ Nanocrystals Go with the Flow: From Formation Mechanism to Continuous Nanomanufacturing